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$K^{*0}$ production in Au+Au collisions at $\sqrt{s_{\rm NN}}$ = 7.7, 11.5, 14.5, 19.6, 27 and 39 GeV from RHIC beam energy scan

The STAR collaboration Abdallah, Mohamed ; Aboona, Bassam ; Adam, Jaroslav ; et al.

Phys.Rev.C 107 (2023) 034907, 2023.

Inspire Record 2642282 DOI 10.17182/hepdata.134956

We report the measurement of $K^{*0}$ meson at midrapidity ($|y|<$ 1.0) in Au+Au collisions at $\sqrt{s_{\rm NN}}$~=~7.7, 11.5, 14.5, 19.6, 27 and 39 GeV collected by the STAR experiment during the RHIC beam energy scan (BES) program. The transverse momentum spectra, yield, and average transverse momentum of $K^{*0}$ are presented as functions of collision centrality and beam energy. The $K^{*0}/K$ yield ratios are presented for different collision centrality intervals and beam energies. The $K^{*0}/K$ ratio in heavy-ion collisions are observed to be smaller than that in small system collisions (e+e and p+p). The $K^{*0}/K$ ratio follows a similar centrality dependence to that observed in previous RHIC and LHC measurements. The data favor the scenario of the dominance of hadronic re-scattering over regeneration for $K^{*0}$ production in the hadronic phase of the medium.

1 data table match query

$p_{\mathrm T}$-differential yield of $\mathrm{K^{*0}} + \bar{\mathrm{K^{*0}}}$ in AuAu collisions at $\sqrt{s_{\mathrm{NN}}}~=~$19.6 GeV (Multiplicity class 60-80%).

A Measurement of $\pi^- p \to K^0(s$) $K^0(s$) $n$ at 22-{GeV}/$c$ and a Systematic Study of the 2++ Meson Spectrum

Longacre, R.S. ; Etkin, A. ; Foley, K.J. ; et al.

Phys.Lett.B 177 (1986) 223-227, 1986.

Inspire Record 230183 DOI 10.17182/hepdata.30232

A coupled channel analysis has been carried out using a new amplitude analysis of the K 0 s K 0 s system produced in the reaction π − p→K 0 s K 0 s n at 22 GeV/ c , which contained about 40 000 new events in the low- t region (| t − t min |<0.1 GeV 2 ). Here only the I G =0 + , J PC =2 ++ amplitude from this analysis is considered, together with available data from other experiments in channels with the same quantum numbers in order to determine which 2 ++ isoscalar mesons have significant pseudoscalar-pseudoscalar couplings. It is found that four poles, f(1270), f'(1525), θ(1690), and f r (1810), are needed, plus a smooth background in order to fit these data; the need for the θ(1690) depends on the J/ψ radiative decay alone, and the f r (1810) is seen only in hadronic production.

0 data tables match query

A Measurement of Strong Coupling Constant $\alpha_s$ to Second Order for 14-{GeV} $\le \sqrt{s} \le$ 46.78-{GeV}

The MARK-J collaboration Adeva, B. ; Becker, U. ; Becker-Szendy, R. ; et al.

Phys.Rev.Lett. 54 (1985) 1750, 1985.

Inspire Record 208007 DOI 10.17182/hepdata.20386

Using the Mark-J detector at the high-energy e+e− collider PETRA, we compare the data from hadron production with the complete second-order QCD calculation over the energy region 22 to 46.78 GeV. We determine the QCD parameter Λ=100±30−45+60 MeV which yields the strong-coupling constant αs=0.12±0.02 for s=44 GeV.

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A Measurement of the Nucleon Structure Functions

Anderson, H.L. ; Fine, R.M. ; Heisterberg, R.H. ; et al.

Phys.Rev.D 20 (1979) 2645, 1979.

Inspire Record 141067 DOI 10.17182/hepdata.4434

Measurements have been made of the inclusive scattering of 96, 147, and 219 GeV muons from hydrogen, and of 147 GeV muons from deuterium. Results are presented for the nucleon structure function F2(x,Q2) [≡νW2(x,Q2)] for 10<ν<200 GeV and 0.2<Q2<80 GeV2. The value of F2 rises with Q2 at small x, and falls with Q2 at large x, in agreement with the ideas of quantum chromodynamics. An average value of the ratio σLσT≡R=0.52±0.35 has been obtained for the region 0.003<x<0.10 and 0.4<Q2<30 GeV2. The values of F2 from this experiment have been combined with those from other charged-lepton scattering experiments to determine moments of the structure functions. The variation with Q2 of these moments is used to derive values for Λ, taking into account corrections up to second order in αs. The fit to the data is very good.

1 data table match query

No description provided.

A Study of the reaction e+ e- ---> mu+ mu- around the Z0 pole

The DELPHI collaboration Abreu, P. ; Adam, W. ; Adami, F. ; et al.

Phys.Lett.B 260 (1991) 240-248, 1991.

Inspire Record 314619 DOI 10.17182/hepdata.29420

Measurements of the cross section and forward-backward asymmetry for the reaction e + e − → μ + μ − using the DELPHI detector at LEP are presented. The data come from a scan around the Z 0 peak at seven centre of mass energies, giving a sample of 3858 events in the polar angle region 22° < θ < 158°. From a fit to the cross section for 43° < θ < 137°, a polar angle region for which the absolute efficiency has been determined, the square root of the product of the Z 0 → e + e − and Z 0 → μ + μ − partial widths is determined to be (Γ e Γ μ ) 1 2 = 85.0 ± 0.9( stat. ) ± 0.8( syst. ) MeV . From this measurement of the partial width, the value of the effective weak mixing angle is determined to be sin 2 ( θ w ) = 0.2267 ± 0.0037 . The ratio of the hadronic to muon pair partial widths is found to be Γ h / Γ μ = 19.89 ± 0.40(stat.) ± 0.19(syst.). The forward-backward asymmetry at the resonance peak energy E CMS = 91.22 GeV is found to be A FB = 0.028 ± 0.020(stat.) ± 0.005(syst.). From a combined fit to the cross section and forward-backward asymmetry data, the products of the electron and muon vector and axial-vector coupling constants are determined to be V e V μ = 0.0024 ± 0.0015(stat.) ± 0.0004(syst.) and A e A μ = 0.253 ± 0.003(stat.) ± 0.003 (syst.). The results are in good agreement with the expectations of the minimal standard model.

0 data tables match query

A new measurement of the Collins and Sivers asymmetries on a transversely polarised deuteron target

The COMPASS collaboration Ageev, E.S. ; Alexakhin, V.Yu. ; Alexandrov, Yu. ; et al.

Nucl.Phys.B 765 (2007) 31-70, 2007.

Inspire Record 729695 DOI 10.17182/hepdata.48535

New high precision measurements of the Collins and Sivers asymmetries of charged hadrons produced in deep-inelastic scattering of muons on a transversely polarised 6LiD target are presented. The data were taken in 2003 and 2004 with the COMPASS spectrometer using the muon beam of the CERN SPS at 160 GeV/c. Both the Collins and Sivers asymmetries turn out to be compatible with zero, within the present statistical errors, which are more than a factor of 2 smaller than those of the published COMPASS results from the 2002 data. The final results from the 2002, 2003 and 2004 runs are compared with naive expectations and with existing model calculations.

1 data table match query

Sivers asymmetry against PT for leading positive hadrons.

A search for heavy Higgs bosons decaying into vector bosons in same-sign two-lepton final states in $pp$ collisions at $\sqrt{s}=13$ TeV with the ATLAS detector

The ATLAS collaboration Aad, Georges ; Abbott, Braden Keim ; Abbott, D.C. ; et al.

JHEP 07 (2023) 200, 2023.

Inspire Record 2176695 DOI 10.17182/hepdata.129285

A search for heavy Higgs bosons produced in association with a vector boson and decaying into a pair of vector bosons is performed in final states with two leptons (electrons or muons) of the same electric charge, missing transverse momentum and jets. A data sample of proton-proton collisions at a centre-of-mass energy of 13 TeV recorded with the ATLAS detector at the Large Hadron Collider between 2015 and 2018 is used. The data correspond to a total integrated luminosity of 139 fb$^{-1}$. The observed data are in agreement with Standard Model background expectations. The results are interpreted using higher-dimensional operators in an effective field theory. Upper limits on the production cross-section are calculated at 95% confidence level as a function of the heavy Higgs boson's mass and coupling strengths to vector bosons. Limits are set in the Higgs boson mass range from 300 to 1500 GeV, and depend on the assumed couplings. The highest excluded mass for a heavy Higgs boson with the coupling combinations explored is 900 GeV. Limits on coupling strengths are also provided.

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Comparison between data and SM predictions for the meff distributions in the boosted SR. The background predictions are obtained through a background-only simultaneous fit and are shown as filled histograms. The entries in overflow are included in the last bin. The size of the combined statistical and systematic uncertainty for the sum of the fitted background is indicated by the hatched band. The ratio of the data to the sum of the fitted background is shown in the lower panel. Two benchmark signal samples, as indicated in the legend, are also shown as unstacked unfilled histograms normalised to the integrated luminosity of the data using the theoretical cross-sections.

rivet Analysis
A study of the energy evolution of event shape distributions and their means with the DELPHI detector at LEP.

The DELPHI collaboration Abdallah, J. ; Abreu, P. ; Adam, W. ; et al.

Eur.Phys.J.C 29 (2003) 285-312, 2003.

Inspire Record 620250 DOI 10.17182/hepdata.13029

Infrared and collinear safe event shape distributions and their mean values are determined in e+e- collisions at centre-of-mass energies between 45 and 202 GeV. A phenomenological analysis based on power correction models including hadron mass effects for both differential distributions and mean values is presented. Using power corrections, alpha_s is extracted from the mean values and shapes. In an alternative approach, renormalisation group invariance (RGI) is used as an explicit constraint, leading to a consistent description of mean values without the need for sizeable power corrections. The QCD beta-function is precisely measured using this approach. From the DELPHI data on Thrust, including data from low energy experiments, one finds beta_0 = 7.86 +/- 0.32 for the one loop coefficient of the beta-function or, assuming QCD, n_f = 4.75 +/- 0.44 for the number of active flavours. These values agree well with the QCD expectation of beta_0=7.67 and n_f=5. A direct measurement of the full logarithmic energy slope excludes light gluinos with a mass below 5 GeV.

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Integrated values of the Energy Energy Correlations Asymmetry (AEEC) for different angular intervals.

Absence of suppression in particle production at large transverse momentum in s(NN)**(1/2) = 200-GeV d + Au collisions.

The PHENIX collaboration Adler, S.S. ; Afanasiev, S. ; Aidala, C. ; et al.

Phys.Rev.Lett. 91 (2003) 072303, 2003.

Inspire Record 621391 DOI 10.17182/hepdata.143668

Transverse momentum spectra of charged hadrons with p_T < 8 GeV/c and neutral pions with p_T < 10 GeV/c have been measured at mid-rapidity by the PHENIX experiment at RHIC in d+Au collisions at sqrt(s_NN) = 200 GeV. The measured yields are compared to those in p+p collisions at the same sqrt(s_NN) scaled up by the number of underlying nucleon-nucleon collisions in d+Au. The yield ratio does not show the suppression observed in central Au+Au collisions at RHIC. Instead, there is a small enhancement in the yield of high momentum particles.

1 data table match query

Nuclear modification factor $R_{dA}$ for ($h^+$+$h^-$)/2 in minimum bias $d$+$Au$.

rivet Analysis
Absolute Drell-Yan dimuon cross sections in 800-GeV/c p p and p d collisions.

The NuSea collaboration Webb, J.C. ; Awes, T.C. ; Brooks, M.L. ; et al.

FERMILAB-PUB-03-302-E, 2003.

Inspire Record 613362 DOI 10.17182/hepdata.41970

The Fermilab E866/NuSea Collaboration has measured the Drell-Yan dimuon cross sections in 800 GeV/$c$ $pp$ and $pd$ collisions. This represents the first measurement of the Drell-Yan cross section in $pp$ collisions over a broad kinematic region and the most extensive study to date of the Drell-Yan cross section in $pd$ collisions. The results indicate that recent global parton distribution fits provide a good description of the light antiquark sea in the nucleon over the Bjorken-$x$ range $0.03 \lesssim x < 0.15$, but overestimate the valence quark distributions as $x \to 1$.

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Measurment of the scaling form of the MU+ MU- cross section in the XL range0.25 to 0.30 from the deuterium target.

Anisotropic flow and flow fluctuations of identified hadrons in Pb$-$Pb collisions at $\sqrt{s_{\mathrm{NN}}}$ = 5.02 TeV

The ALICE collaboration Acharya, Shreyasi ; Adamova, Dagmar ; Adler, Alexander ; et al.

JHEP 05 (2023) 243, 2023.

Inspire Record 2093750 DOI 10.17182/hepdata.133152

The first measurements of elliptic flow of $\pi^\pm$, ${\rm K}^\pm$, p+$\overline{\rm p}$, ${\rm K_{S}^0}$, $\Lambda$+$\overline{\Lambda}$, $\phi$, $\Xi^-$+$\Xi^+$, and $\Omega^-$+$\Omega^+$ using multiparticle cumulants in Pb$-$Pb collisions at $\sqrt{s_{\rm NN}}$ = 5.02 TeV are presented. Results obtained with two- ($v_2\{2\}$) and four-particle cumulants ($v_2\{4\}$) are shown as a function of transverse momentum, $p_{\rm T}$, for various collision centrality intervals. Combining the data for both $v_2\{2\}$ and $v_2\{4\}$ also allows us to report the first measurements of the mean elliptic flow, elliptic flow fluctuations, and relative elliptic flow fluctuations for various hadron species. These observables probe the event-by-event eccentricity fluctuations in the initial state and the contributions from the dynamic evolution of the expanding quark-gluon plasma. The characteristic features observed in previous $p_{\rm T}$-differential anisotropic flow measurements for identified hadrons with two-particle correlations, namely the mass ordering at low $p_{\rm T}$ and the approximate scaling with the number of constituent quarks at intermediate $p_{\rm T}$, are similarly present in the four-particle correlations and the combinations of $v_2\{2\}$ and $v_2\{4\}$. In addition, a particle species dependence of flow fluctuations is observed that could indicate a significant contribution from final state hadronic interactions. The comparison between experimental measurements and CoLBT model calculations, which combine the various physics processes of hydrodynamics, quark coalescence, and jet fragmentation, illustrates their importance over a wide $p_{\rm T}$ range.

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The $p_{T}$-differential $v_2$ measured with two-particle correlations with a pseudorapidity gap of $|\Delta \eta| > 0.8$ for different particle species and centralities in Pb--Pb collisions at $\sqrt{s_{\mathrm{NN}}} = 5.02$ TeV.

Anomalous centrality evolution of two-particle angular correlations from Au-Au collisions at $\sqrt{s_{\rm NN}}$ = 62 and 200 GeV

The STAR collaboration Agakishiev, G. ; Aggarwal, M.M. ; Ahammed, Z. ; et al.

Phys.Rev.C 86 (2012) 064902, 2012.

Inspire Record 927960 DOI 10.17182/hepdata.101346

We present two-dimensional (2D) two-particle angular correlations on relative pseudorapidity $\eta$ and azimuth $\phi$ for charged particles from Au-Au collisions at $\sqrt{s_{\rm NN}} = 62$ and 200 GeV with transverse momentum $p_t \geq 0.15$ GeV/$c$, $|\eta| \leq 1$ and $2\pi$ azimuth. Observed correlations include a {same-side} (relative azimuth $< \pi/2$) 2D peak, a closely-related away-side azimuth dipole, and an azimuth quadrupole conventionally associated with elliptic flow. The same-side 2D peak and away-side dipole are explained by semihard parton scattering and fragmentation (minijets) in proton-proton and peripheral nucleus-nucleus collisions. Those structures follow N-N binary-collision scaling in Au-Au collisions until mid-centrality where a transition to a qualitatively different centrality trend occurs within a small centrality interval. Above the transition point the number of same-side and away-side correlated pairs increases rapidly {relative to} binary-collision scaling, the $\eta$ width of the same-side 2D peak also increases rapidly ($\eta$ elongation) and the $\phi$ width actually decreases significantly. Those centrality trends are more remarkable when contrasted with expectations of jet quenching in a dense medium. Observed centrality trends are compared to {\sc hijing} predictions and to the expected trends for semihard parton scattering and fragmentation in a thermalized opaque medium. We are unable to reconcile a semihard parton scattering and fragmentation origin for the observed correlation structure and centrality trends with heavy ion collision scenarios which invoke rapid parton thermalization. On the other hand, if the collision system is effectively opaque to few-GeV partons the observations reported here would be inconsistent with a minijet picture.

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FIG. 3. Fit parameters for $\left(\eta_{\Delta}, \phi_{\Delta}\right)$ correlation data from Au-Au collisions at $\sqrt{s_{N N}}=62$ (open symbols) and 200 GeV (solid symbols) versus centrality measure $\nu$ computed at fixed energy $(200 \mathrm{GeV})$. The SS $2 \mathrm{D}$ Gaussian amplitudes, $\eta_{\Delta}$ widths, and $\phi_{\Delta}$ widths are shown in the left, center, and right panels, respectively of the top row. The bottom row shows from left to right the amplitudes for the dipole, quadrupole, and SS peak width aspect ratio $\sigma_{\eta_{\Delta}} / \sigma_{\phi_{\Delta}} .$ Fitting errors are indicated by error bars where larger than the symbols. Solid lines connect the points for clarity. The dotted and dashed curves indicate Glauber linear superposition estimates for 62 - and 200 -GeV peak amplitudes respectively, as discussed in the text. The quadrupole data are consistent with Ref. [60]. The hatched regions indicate the full range of systematic uncertainties listed in Appendix F. The vertical dark bands indicate estimated $v$ equivalents for $N-N$ collisions and $b=0$ Au-Au collisions.

Azimuthal angle correlations for rapidity separated hadron pairs in d + Au collisions at s(NN)**(1/2) = 200-GeV.

The PHENIX collaboration Adler, S.S. ; Afanasiev, S. ; Aidala, C. ; et al.

Phys.Rev.Lett. 96 (2006) 222301, 2006.

Inspire Record 712584 DOI 10.17182/hepdata.142147

We report on two-particle azimuthal angle correlations between charged hadrons at forward/backward (deuteron/gold going direction) rapidity and charged hadrons at mid-rapidity in deuteron-gold (d+Au) and proton-proton (p+p) collisions at sqrt(s_NN) = 200 GeV. Jet structures are observed in the correlations which we quantify in terms of the conditional yield and angular width of away side partners. The kinematic region studied here samples partons in the gold nucleus carrying nucleon momentum fraction x~0.1 to x~0.01. Within this range, we find no x dependence of the jet structure in d+Au collisions.

1 data table match query

$I_{dAu}$ vs. $p_T^{assoc}$ for different centrality, $p_T^{trig}$ and $\eta^{trig}$ bins.

Azimuthal anisotropy measurement of (multi-)strange hadrons in Au+Au collisions at $\sqrt{s_{\text{NN}}}$ = 54.4 GeV

The STAR collaboration Abdallah, Mohamed ; Aboona, Bassam ; Adam, Jaroslav ; et al.

Phys.Rev.C 107 (2023) 024912, 2023.

Inspire Record 2635688 DOI 10.17182/hepdata.130768

Azimuthal anisotropy of produced particles is one of the most important observables used to access the collective properties of the expanding medium created in relativistic heavy-ion collisions. In this paper, we present second ($v_{2}$) and third ($v_{3}$) order azimuthal anisotropies of $K_{S}^{0}$, $\phi$, $\Lambda$, $\Xi$ and $\Omega$ at mid-rapidity ($|y|<$1) in Au+Au collisions at $\sqrt{s_{\text{NN}}}$ = 54.4 GeV measured by the STAR detector. The $v_{2}$ and $v_{3}$ are measured as a function of transverse momentum and centrality. Their energy dependence is also studied. $v_{3}$ is found to be more sensitive to the change in the center-of-mass energy than $v_{2}$. Scaling by constituent quark number is found to hold for $v_{2}$ within 10%. This observation could be evidence for the development of partonic collectivity in 54.4 GeV Au+Au collisions. Differences in $v_{2}$ and $v_{3}$ between baryons and anti-baryons are presented, and ratios of $v_{3}$/$v_{2}^{3/2}$ are studied and motivated by hydrodynamical calculations. The ratio of $v_{2}$ of $\phi$ mesons to that of anti-protons ($v_{2}(\phi)/v_{2}(\bar{p})$) shows centrality dependence at low transverse momentum, presumably resulting from the larger effects from hadronic interactions on anti-proton $v_{2}$.

1 data table match query

$v_{3}(p_{T})$ for $\bar{\Lambda}$ (Centrality:10-40%)

Balance Functions from Au+Au, d+Au, and p+p Collisions at $\sqrt{s_{NN}}$ = 200 GeV

The STAR collaboration Aggarwal, M.M. ; Ahammed, Z. ; Alakhverdyants, A.V. ; et al.

Phys.Rev.C 82 (2010) 024905, 2010.

Inspire Record 855746 DOI 10.17182/hepdata.101340

Balance functions have been measured for charged particle pairs, identified charged pion pairs, and identified charged kaon pairs in Au+Au, d+Au, and p+p collisions at $\sqrt{s_{NN}}$ = 200 GeV at the Relativistic Heavy Ion Collider using the STAR detector. These balance functions are presented in terms of relative pseudorapidity, $\Delta \eta$, relative rapidity, $\Delta y$, relative azimuthal angle, $\Delta \phi$, and invariant relative momentum, $q_{\rm inv}$. In addition, balance functions are shown in terms of the three components of $q_{\rm inv}$: $q_{\rm long}$, $q_{\rm out}$, and $q_{\rm side}$. For charged particle pairs, the width of the balance function in terms of $\Delta \eta$ scales smoothly with the number of participating nucleons, while HIJING and UrQMD model calculations show no dependence on centrality or system size. For charged particle and charged pion pairs, the balance functions widths in terms of $\Delta \eta$ and $\Delta y$ are narrower in central Au+Au collisions than in peripheral collisions. The width for central collisions is consistent with thermal blast-wave models where the balancing charges are highly correlated in coordinate space at breakup. This strong correlation might be explained either by delayed hadronization or by limited diffusion during the reaction. Furthermore, the narrowing trend is consistent with the lower kinetic temperatures inherent to more central collisions. In contrast, the width of the balance function for charged kaon pairs in terms of $\Delta y$ shows little centrality dependence, which may signal a different production mechanism for kaons. The widths of the balance functions for charged pions and kaons in terms of $q_{\rm inv}$ narrow in central collisions compared to peripheral collisions, which may be driven by the change in the kinetic temperature.

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(Color online) The widths for the balance functions for pions in terms of $q_{long}$, $q_{out}$, and $q_{side}$ compared with UrQMD calculations.

Beam Energy Dependence of Jet-Quenching Effects in Au+Au Collisions at $\sqrt{s_{_{ \mathrm{NN}}}}$ = 7.7, 11.5, 14.5, 19.6, 27, 39, and 62.4 GeV

The STAR collaboration Adamczyk, L. ; Adams, J.R. ; Adkins, J.K. ; et al.

Phys.Rev.Lett. 121 (2018) 032301, 2018.

Inspire Record 1609067 DOI 10.17182/hepdata.100537

We report measurements of the nuclear modification factor, $R_{ \mathrm{CP}}$, for charged hadrons as well as identified $\pi^{+(-)}$, $K^{+(-)}$, and $p(\overline{p})$ for Au+Au collision energies of $\sqrt{s_{_{ \mathrm{NN}}}}$ = 7.7, 11.5, 14.5, 19.6, 27, 39, and 62.4 GeV. We observe a clear high-$p_{\mathrm{T}}$ net suppression in central collisions at 62.4 GeV for charged hadrons which evolves smoothly to a large net enhancement at lower energies. This trend is driven by the evolution of the pion spectra, but is also very similar for the kaon spectra. While the magnitude of the proton $R_{ \mathrm{CP}}$ at high $p_{\mathrm{T}}$ does depend on collision energy, neither the proton nor the anti-proton $R_{ \mathrm{CP}}$ at high $p_{\mathrm{T}}$ exhibit net suppression at any energy. A study of how the binary collision scaled high-$p_{\mathrm{T}}$ yield evolves with centrality reveals a non-monotonic shape that is consistent with the idea that jet-quenching is increasing faster than the combined phenomena that lead to enhancement.

1 data table match query

$\\p$ $\frac{1}{2\pi p_{T}}$ * $\frac{d^{2}N}{d\eta dp_{T}}$ $\pm$ stat. $\pm$ sys. $(GeV/c)^{-2}$ for $\sqrt{s_{NN}}$ = 11.5 GeV/c

rivet Analysis
Beam Energy Dependence of the Third Harmonic of Azimuthal Correlations in Au+Au Collisions at RHIC

The STAR collaboration Adamczyk, L. ; Adkins, J.K. ; Agakishiev, G. ; et al.

Phys.Rev.Lett. 116 (2016) 112302, 2016.

Inspire Record 1414638 DOI 10.17182/hepdata.72069

We present results from a harmonic decomposition of two-particle azimuthal correlations measured with the STAR detector in Au+Au collisions for energies ranging from $\sqrt{s_{NN}}=7.7$ GeV to 200 GeV. The third harmonic $v_3^2\{2\}=\langle \cos3(\phi_1-\phi_2)\rangle$, where $\phi_1-\phi_2$ is the angular difference in azimuth, is studied as a function of the pseudorapidity difference between particle pairs $\Delta\eta = \eta_1-\eta_2$. Non-zero {\vthree} is directly related to the previously observed large-$\Delta\eta$ narrow-$\Delta\phi$ ridge correlations and has been shown in models to be sensitive to the existence of a low viscosity Quark Gluon Plasma (QGP) phase. For sufficiently central collisions, $v_3^2\{2\}$ persist down to an energy of 7.7 GeV suggesting that QGP may be created even in these low energy collisions. In peripheral collisions at these low energies however, $v_3^2\{2\}$ is consistent with zero. When scaled by pseudorapidity density of charged particle multiplicity per participating nucleon pair, $v_3^2\{2\}$ for central collisions shows a minimum near {\snn}$=20$ GeV.

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Representative results on $v_3^2\{2\}$ from Au+Au collisions as a function of $\Delta\eta$ for charged hadrons with pT > 0.2 GeV/c and |$\eta$| < 1.

Bose-Einstein correlations of charged pion pairs in Au + Au collisions at s(NN)**(1/2) = 200-GeV.

The PHENIX collaboration Adler, S.S. ; Afanasiev, S. ; Aidala, C. ; et al.

Phys.Rev.Lett. 93 (2004) 152302, 2004.

Inspire Record 642225 DOI 10.17182/hepdata.140436

Bose-Einstein correlations of identically charged pion pairs were measured by the PHENIX experiment at mid-rapidity in Au+Au collisions at $\sqrt{s_{\rm NN}}$ = 200 GeV. The Bertsch-Pratt radius parameters were determined as a function of the transverse momentum of the pair and as a function of the centrality of the collision. Using the \it{full} Coulomb correction, the ratio $R_{\rm out}/R_{\rm side}$ is smaller than unity for $<k_{\rm T}>$ from 0.25 to 1.2 GeV/c and for all measured centralities. However, using recently developed partial Coulomb correction methods, we find that $R_{\rm out}/R_{\rm side}$ is 0.8-1.1 for the measured $<k_{\rm T}>$ range, and approximately constant at unity with the number of participants.

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The $k_T$ dependence of the Bertsch-Pratt radius parameters and $\lambda$ for charged pions for 0-30% centrality. Filled triangles show the results from fits to a core-halo structure by Eq. 2, with statistical error bars and systematic error bands. Open circles and squares show the results from the full (Eq. 1) and 50% partial (Eq. 3) Coulomb corrections with statistical error bars, respectively. Results at 130 GeV by PHENIX are given by filled circles.

Center of mass energy and system-size dependence of photon production at forward rapidity at RHIC

The STAR collaboration Abelev, B.I. ; Aggarwal, M.M. ; Ahammed, Z. ; et al.

Nucl.Phys.A 832 (2010) 134-147, 2010.

Inspire Record 822997 DOI 10.17182/hepdata.101347

We present the multiplicity and pseudorapidity distributions of photons produced in Au+Au and Cu+Cu collisions at \sqrt{s_NN} = 62.4 and 200 GeV. The photons are measured in the region -3.7 < \eta < -2.3 using the photon multiplicity detector in the STAR experiment at RHIC. The number of photons produced per average number of participating nucleon pairs increases with the beam energy and is independent of the collision centrality. For collisions with similar average numbers of participating nucleons the photon multiplicities are observed to be similar for Au+Au and Cu+Cu collisions at a given beam energy. The ratios of the number of charged particles to photons in the measured pseudorapidity range are found to be 1.4 +/- 0.1 and 1.2 +/- 0.1 for \sqrt{s_NN} = 62.4 GeV and 200 GeV, respectively. The energy dependence of this ratio could reflect varying contributions from baryons to charged particles, while mesons are the dominant contributors to photon production in the given kinematic region. The photon pseudorapidity distributions normalized by average number of participating nucleon pairs, when plotted as a function of \eta - ybeam, are found to follow a longitudinal scaling independent of centrality and colliding ion species at both beam energies.

1 data table match query

Fig. 3. (Color online.) Photon pseudorapidity distributions for $\mathrm{Au}+\mathrm{Au}$ and $\mathrm{Cu}+\mathrm{Cu}$ at $\sqrt{\mathrm{s}_{\mathrm{NN}}}=62.4$ and $200\mathrm{GeV}$. The results for several centrality classes are shown. The solid curves are results of HIJING simulations for central $(0-5 \%$ for $\mathrm{Au}+\mathrm{Au}$ and $0-10 \%$ for $\mathrm{Cu}+\mathrm{Cu})$ and $30-40 \%$ mid-central collisions. The errors shown are systematic, statistical errors are negligible in comparison. NOTE: For points with invisible error bars, the point size was considered as an absolute upper limit for the uncertainty.

Centrality and pseudorapidity dependence of charged hadron production at intermediate p(T) in Au + Au collisions at s(NN)**(1/2) = 130-GeV

The STAR collaboration Adams, J. ; Aggarwal, M.M. ; Ahammed, Z. ; et al.

Phys.Rev.C 70 (2004) 044901, 2004.

Inspire Record 648464 DOI 10.17182/hepdata.98858

We present STAR measurements of charged hadron production as a function of centrality in Au + Au collisions at sqrt(s_NN) = 130 GeV. The measurements cover a phase space region of 0.2 < p_T < 6.0 GeV/c in transverse momentum and -1 < eta < 1 in pseudorapidity. Inclusive transverse momentum distributions of charged hadrons in the pseudorapidity region 0.5 < |eta| < 1 are reported and compared to our previously published results for |eta| < 0.5. No significant difference is seen for inclusive p_T distributions of charged hadrons in these two pseudorapidity bins. We measured dN/deta distributions and truncated mean p_T in a region of p_T > p_T^cut, and studied the results in the framework of participant and binary scaling. No clear evidence is observed for participant scaling of charged hadron yield in the measured p_T region. The relative importance of hard scattering process is investigated through binary scaling fraction of particle production.

1 data table match query

Table 3a: Number of binary collisions and participants

Ratio of the number of participants Npart or the number of binary collisions Nbin determined from different models to that from Monte Carlo Glauber calculation.

Centrality and transverse momentum dependence of elliptic flow of multi-strange hadrons and $\phi$ meson in Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV

The STAR collaboration Adamczyk, L. ; Adkins, J.K. ; Agakishiev, G. ; et al.

Phys.Rev.Lett. 116 (2016) 062301, 2016.

Inspire Record 1383879 DOI 10.17182/hepdata.71571

We present high precision measurements of elliptic flow near midrapidity ($|y|<1.0$) for multi-strange hadrons and $\phi$ meson as a function of centrality and transverse momentum in Au+Au collisions at center of mass energy $\sqrt{s_{NN}}=$ 200 GeV. We observe that the transverse momentum dependence of $\phi$ and $\Omega$ $v_{2}$ is similar to that of $\pi$ and $p$, respectively, which may indicate that the heavier strange quark flows as strongly as the lighter up and down quarks. This observation constitutes a clear piece of evidence for the development of partonic collectivity in heavy-ion collisions at the top RHIC energy. Number of constituent quark scaling is found to hold within statistical uncertainty for both 0-30$\%$ and 30-80$\%$ collision centrality. There is an indication of the breakdown of previously observed mass ordering between $\phi$ and proton $v_{2}$ at low transverse momentum in the 0-30$\%$ centrality range, possibly indicating late hadronic interactions affecting the proton $v_{2}$.

1 data table match query

No description provided.

Version 2
Centrality dependence of identified particles in relativistic heavy ion collisions at sqrt(s)= 7.7-62.4 GeV

The STAR collaboration Adamczyk, L. ; Adkins, J.K. ; Agakishiev, G. ; et al.

Phys.Rev.C 93 (2016) 014907, 2016.

Inspire Record 1395151 DOI 10.17182/hepdata.71527

Elliptic flow (v_2) values for identified particles at midrapidity in Au + Au collisions measured by the STAR experiment in the Beam Energy Scan at the Relativistic Heavy Ion Collider at sqrt{s_{NN}}= 7.7--62.4 GeV are presented for three centrality classes. The centrality dependence and the data at sqrt{s_{NN}}= 14.5 GeV are new. Except at the lowest beam energies we observe a similar relative v_2 baryon-meson splitting for all centrality classes which is in agreement within 15% with the number-of-constituent quark scaling. The larger v_2 for most particles relative to antiparticles, already observed for minimum bias collisions, shows a clear centrality dependence, with the largest difference for the most central collisions. Also, the results are compared with A Multiphase Transport Model and fit with a Blast Wave model.

2 data tables match query

No description provided.

No description provided.

Centrality dependence of the high p(T) charged hadron suppression in Au + Au collisions at s(NN)**(1/2) = 130-GeV.

The PHENIX collaboration Adcox, K. ; Adler, Stephen Scott ; Ajitanand, N.N. ; et al.

Phys.Lett.B 561 (2003) 82-92, 2003.

Inspire Record 590820 DOI 10.17182/hepdata.141648

PHENIX has measured the centrality dependence of charged hadron p_T spectra from central Au+Au collisions at sqrt(s_NN)=130 GeV. The truncated mean p_T decreases with centrality for p_T > 2 GeV/c, indicating an apparent reduction of the contribution from hard scattering to high p_T hadron production. For central collisions the yield at high p_T is shown to be suppressed compared to binary nucleon-nucleon collision scaling of p+p data. This suppression is monotonically increasing with centrality, but most of the change occurs below 30% centrality, i.e. for collisions with less than about 140 participating nucleons. The observed p_T and centrality dependence is consistent with the particle production predicted by models including hard scattering and subsequent energy loss of the scattered partons in the dense matter created in the collisions.

1 data table match query

The ratio $p/h$ represents the proton plus anti-proton yield relative to the total charged hadron multiplicity. This shows the $p_T$ dependence of $p/h$ for minimum bias events.

Charged Particle Production in Proton-, Deuteron-, Oxygen- and Sulphur-Nucleus Collisions at 200 GeV per Nucleon

The NA35 collaboration Alber, T. ; Appelshauser, H. ; Bachler, J. ; et al.

Eur.Phys.J.C 2 (1998) 643-659, 1998.

Inspire Record 450611 DOI 10.17182/hepdata.34289

The transverse momentum and rapidity distributions of net protons and negatively charged hadrons have been measured for minimum bias proton-nucleus and deuteron-gold interactions, as well as central oxygen-gold and sulphur-nucleus collisions at 200 GeV per nucleon. The rapidity density of net protons at midrapidity in central nucleus-nucleus collisions increases both with target mass for sulphur projectiles and with the projectile mass for a gold target. The shape of the rapidity distributions of net protons forward of midrapidity for d+Au and central S+Au collisions is similar. The average rapidity loss is larger than 2 units of rapidity for reactions with the gold target. The transverse momentum spectra of net protons for all reactions can be described by a thermal distribution with `temperatures' between 145 +- 11 MeV (p+S interactions) and 244 +- 43 MeV (central S+Au collisions). The multiplicity of negatively charged hadrons increases with the mass of the colliding system. The shape of the transverse momentum spectra of negatively charged hadrons changes from minimum bias p+p and p+S interactions to p+Au and central nucleus-nucleus collisions. The mean transverse momentum is almost constant in the vicinity of midrapidity and shows little variation with the target and projectile masses. The average number of produced negatively charged hadrons per participant baryon increases slightly from p+p, p+A to central S+S,Ag collisions.

1 data table match query

Rapidity distributions of net hyperons (Lambda-Lambdabar) for central S+S (0.5 < y < 3.0) collisions at 200 GeV/nucleon.

Charged hadron multiplicity fluctuations in Au+Au and Cu+Cu collisions from sqrt(s_NN) = 22.5 to 200 GeV

The PHENIX collaboration Adare, A. ; Adler, S.S. ; Afanasiev, S. ; et al.

Phys.Rev.C 78 (2008) 044902, 2008.

Inspire Record 785509 DOI 10.17182/hepdata.143616

A comprehensive survey of event-by-event fluctuations of charged hadron multiplicity in relativistic heavy ions is presented. The survey covers Au+Au collisions at sqrt(s_NN) = 62.4 and 200 GeV, and Cu+Cu collisions sqrt(s_NN) = 22.5, 62.4, and 200 GeV. Fluctuations are measured as a function of collision centrality, transverse momentum range, and charge sign. After correcting for non-dynamical fluctuations due to fluctuations in the collision geometry within a centrality bin, the remaining dynamical fluctuations expressed as the variance normalized by the mean tend to decrease with increasing centrality. The dynamical fluctuations are consistent with or below the expectation from a superposition of participant nucleon-nucleon collisions based upon p+p data, indicating that this dataset does not exhibit evidence of critical behavior in terms of the compressibility of the system. An analysis of Negative Binomial Distribution fits to the multiplicity distributions demonstrates that the heavy ion data exhibit weak clustering properties.

2 data tables match query

The mean from the NBD fit as a function of $N_{part}$ for 200 GeV Au+Au collisions over the range 0.2 < $p_T$ < 2.0 GeV/$c$.

The mean from the NBD fit as a function of $N_{part}$ for 62.4 GeV Au+Au collisions over the range 0.2 < $p_T$ < 2.0 GeV/$c$.

Charged pion production in 2-AGeV to 8-AGeV central Au + Au collisions.

The E-0895 collaboration Klay, J.L. ; Ajitanand, N.N. ; Alexander, J.M. ; et al.

Phys.Rev.C 68 (2003) 054905, 2003.

Inspire Record 622260 DOI 10.17182/hepdata.4989

Momentum spectra of charged pions over nearly full rapidity coverage from target to beam rapidity have been measured in the 0-5% most central Au+Au collisions in the beam energy range from 2 to 8 AGeV by the E895 Experiment. Using a thermal parameterization to fit the transverse mass spectra, rapidity density distributions are extracted. The observed spectra are compared with predictions from the RQMD v2.3 cascade model and also to a thermal model including longitudinal flow. The total 4$\pi$ yields of the charged pions are used to infer an initial state entropy produced in the collisions.

1 data table match query

No description provided.

Charged-hadron production in $pp$, $p$+Pb, Pb+Pb, and Xe+Xe collisions at $\sqrt{s_{_\text{NN}}}=5$ TeV with the ATLAS detector at the LHC

The ATLAS collaboration Aad, Georges ; Abbott, Braden Keim ; Abeling, Kira ; et al.

JHEP 07 (2023) 074, 2023.

Inspire Record 2601282 DOI 10.17182/hepdata.135676

This paper presents measurements of charged-hadron spectra obtained in $pp$, $p$+Pb, and Pb+Pb collisions at $\sqrt{s}$ or $\sqrt{s_{_\text{NN}}}=5.02$ TeV, and in Xe+Xe collisions at $\sqrt{s_{_\text{NN}}}=5.44$ TeV. The data recorded by the ATLAS detector at the LHC have total integrated luminosities of 25 pb${}^{-1}$, 28 nb${}^{-1}$, 0.50 nb${}^{-1}$, and 3 $\mu$b${}^{-1}$, respectively. The nuclear modification factors $R_{p\text{Pb}}$ and $R_\text{AA}$ are obtained by comparing the spectra in heavy-ion and $pp$ collisions in a wide range of charged-particle transverse momenta and pseudorapidity. The nuclear modification factor $R_{p\text{Pb}}$ shows a moderate enhancement above unity with a maximum at $p_{\mathrm{T}} \approx 3$ GeV; the enhancement is stronger in the Pb-going direction. The nuclear modification factors in both Pb+Pb and Xe+Xe collisions feature a significant, centrality-dependent suppression. They show a similar distinct $p_{\mathrm{T}}$-dependence with a local maximum at $p_{\mathrm{T}} \approx 2$ GeV and a local minimum at $p_{\mathrm{T}} \approx 7$ GeV. This dependence is more distinguishable in more central collisions. No significant $|\eta|$-dependence is found. A comprehensive comparison with several theoretical predictions is also provided. They typically describe $R_\text{AA}$ better in central collisions and in the $p_{\mathrm{T}}$ range from about 10 to 100 GeV.

1 data table match query

Charged-hadron spectrum in the centrality interval 10-20% for Xe+Xe, divided by 〈TAA〉. The systematic uncertainties are described in the section 7 of the paper. The total systematic uncertainties are determined by adding the contributions from all relevant sources in quadrature.

rivet Analysis
Charged-particle multiplicities in pp interactions measured with the ATLAS detector at the LHC

The ATLAS collaboration Aad, G. ; Abbott, B. ; Abdallah, J. ; et al.

New J.Phys. 13 (2011) 053033, 2011.

Inspire Record 882098 DOI 10.17182/hepdata.57077

Measurements are presented from proton-proton collisions at centre-of-mass energies of sqrt(s) = 0.9, 2.36 and 7 TeV recorded with the ATLAS detector at the LHC. Events were collected using a single-arm minimum-bias trigger. The charged-particle multiplicity, its dependence on transverse momentum and pseudorapidity and the relationship between the mean transverse momentum and charged-particle multiplicity are measured. Measurements in different regions of phase-space are shown, providing diffraction-reduced measurements as well as more inclusive ones. The observed distributions are corrected to well-defined phase-space regions, using model-independent corrections. The results are compared to each other and to various Monte Carlo models, including a new AMBT1 PYTHIA 6 tune. In all the kinematic regions considered, the particle multiplicities are higher than predicted by the Monte Carlo models. The central charged-particle multiplicity per event and unit of pseudorapidity, for tracks with pT >100 MeV, is measured to be 3.483 +- 0.009 (stat) +- 0.106 (syst) at sqrt(s) = 0.9 TeV and 5.630 +- 0.003 (stat) +- 0.169 (syst) at sqrt(s) = 7 TeV.

1 data table match query

Average transverse momentum in proton-proton collisions at a centre-of mass energy of 900 GeV as a function of the number of charged particles in the event for events with the number of charged particles >=1 having transverse momentum >500 MeV and absolute(pseudorapidity) <2.5.

Charged-particle multiplicity distributions over a wide pseudorapidity range in proton-proton collisions at $\mathbf{\sqrt{s}=}$ 0.9, 7 and 8 TeV

The ALICE collaboration Acharya, S. ; Adamová, D. ; Adolfsson, J. ; et al.

Eur.Phys.J.C 77 (2017) 852, 2017.

Inspire Record 1614477 DOI 10.17182/hepdata.78802

We present the charged-particle multiplicity distributions over a wide pseudorapidity range ($-3.4<\eta<5.0$) for pp collisions at $\sqrt{s}=$ 0.9, 7, and 8 TeV at the LHC. Results are based on information from the Silicon Pixel Detector and the Forward Multiplicity Detector of ALICE, extending the pseudorapidity coverage of the earlier publications and the high-multiplicity reach. The measurements are compared to results from the CMS experiment and to PYTHIA, PHOJET and EPOS LHC event generators, as well as IP-Glasma calculations.

1 data table match query

Multiplicity distribution in the pseudorapidity region -2.4 to 2.4 for INEL collisions at a centre-of-mass energy of 7000 GeV.

rivet Analysis
Charged-particle multiplicity measurement in proton-proton collisions at sqrt(s) = 0.9 and 2.36 TeV with ALICE at LHC

The ALICE collaboration Aamodt, K. ; Abel, N. ; Abeysekara, U. ; et al.

Eur.Phys.J.C 68 (2010) 89-108, 2010.

Inspire Record 852450 DOI 10.17182/hepdata.54742

Charged-particle production was studied in proton-proton collisions collected at the LHC with the ALICE detector at centre-of-mass energies 0.9 TeV and 2.36 TeV in the pseudorapidity range |$\eta$| < 1.4. In the central region (|$\eta$| < 0.5), at 0.9 TeV, we measure charged-particle pseudorapidity density dNch/deta = 3.02 $\pm$ 0.01 (stat.) $^{+0.08}_{-0.05}$ (syst.) for inelastic interactions, and dNch/deta = 3.58 $\pm$ 0.01 (stat.) $^{+0.12}_{-0.12}$ (syst.) for non-single-diffractive interactions. At 2.36 TeV, we find dNch/deta = 3.77 $\pm$ 0.01 (stat.) $^{+0.25}_{-0.12}$ (syst.) for inelastic, and dNch/deta = 4.43 $\pm$ 0.01 (stat.) $^{+0.17}_{-0.12}$ (syst.) for non-single-diffractive collisions. The relative increase in charged-particle multiplicity from the lower to higher energy is 24.7% $\pm$ 0.5% (stat.) $^{+5.7}_{-2.8}$% (syst.) for inelastic and 23.7% $\pm$ 0.5% (stat.) $^{+4.6}_{-1.1}$% (syst.) for non-single-diffractive interactions. This increase is consistent with that reported by the CMS collaboration for non-single-diffractive events and larger than that found by a number of commonly used models. The multiplicity distribution was measured in different pseudorapidity intervals and studied in terms of KNO variables at both energies. The results are compared to proton-antiproton data and to model predictions.

1 data table match query

Mean CQ moments of the multiplicity distributions for the pseudorapidity range -1.0 to 1.0 in P P NSD collisions at centre-of-mass energies 900 and 2360 GeV.

Charged-particle production as a function of the relative transverse activity classifier in pp, p$-$Pb, and Pb$-$Pb collisions at the LHC

The ALICE collaboration Acharya, Shreyasi ; Adamova, Dagmar ; Aglieri Rinella, Gianluca ; et al.

JHEP 01 (2024) 199, 2024.

Inspire Record 2709103 DOI 10.17182/hepdata.146104

Measurements of charged-particle production in pp, p$-$Pb, and Pb$-$Pb collisions in the toward, away, and transverse regions with the ALICE detector are discussed. These regions are defined event-by-event relative to the azimuthal direction of the charged trigger particle, which is the reconstructed particle with the largest transverse momentum ($p_{\mathrm{T}}^{\rm trig}$) in the range $8<p_{\mathrm{T}}^{\rm trig}<15$ GeV$/c$. The toward and away regions contain the primary and recoil jets, respectively; both regions are accompanied by the underlying event (UE). In contrast, the transverse region perpendicular to the direction of the trigger particle is dominated by the so-called UE dynamics, and includes also contributions from initial- and final-state radiation. The relative transverse activity classifier, $R_{\mathrm{T}}=N_{\mathrm{ch}}^{\mathrm{T}}/\langle N_{\mathrm{ch}}^{\mathrm{T}}\rangle$, is used to group events according to their UE activity, where $N_{\mathrm{ch}}^{\mathrm{T}}$ is the charged-particle multiplicity per event in the transverse region and $\langle N_{\mathrm{ch}}^{\mathrm{T}}\rangle$ is the mean value over the whole analysed sample. The energy dependence of the $R_{\mathrm{T}}$ distributions in pp collisions at $\sqrt{s}=2.76$, 5.02, 7, and 13 TeV is reported, exploring the Koba-Nielsen-Olesen (KNO) scaling properties of the multiplicity distributions. The first measurements of charged-particle $p_{\rm T}$ spectra as a function of $R_{\mathrm{T}}$ in the three azimuthal regions in pp, p$-$Pb, and Pb$-$Pb collisions at $\sqrt{s_{\rm NN}}=5.02$ TeV are also reported. Data are compared with predictions obtained from the event generators PYTHIA 8 and EPOS LHC. This set of measurements is expected to contribute to the understanding of the origin of collective-like effects in small collision systems (pp and p$-$Pb).

1 data table match query

Average $p_\mathrm{T}$ as a function of $R_\mathrm{T}$ in the transverse region using events with trigger particles $8<p_\mathrm{T}^\mathrm{trig}<15~\mathrm{GeV}/c$ in the pseudorapidity range of $|\eta|<0.8$ and with $p_\mathrm{T}>0.5~\mathrm{GeV}/c$ for Pb-Pb collisions at $\sqrt{s_\mathrm{NN}}=5.02~\mathrm{TeV}$

Cold Nuclear Matter Effects on J/Psi as Constrained by Deuteron-Gold Measurements at sqrt(s_NN) = 200 GeV

The PHENIX collaboration Adare, A. ; Adler, S.S. ; Afanasiev, S. ; et al.

Phys.Rev.C 77 (2008) 024912, 2008.

Inspire Record 768530 DOI 10.17182/hepdata.57373

All of the experimental data points presented in the original paper are correct and unchanged (including statistical and systematic uncertainties). However, herein we correct a comparison between the experimental data and a theoretical picture, because we discovered a mistake in the code used. All of the most probable sigma_breakup values differ by less than 0.4 mb from those originally presented. However, the one standard deviation uncertainties (that include contributions from both the statistical and systematic uncertainties on the experimental data points) are approximately 30-60% larger than originally reported. We give a table of the new comparison results and corrected versions of Figs. 8-11 of the original paper and we note that no correction is needed for results from the data-driven method in Fig. 13.

1 data table match query

Breakup cross section of c-c_bar pairs inside cold nuclear matter for different ranges of rapidity.The breakup cross section is calculated with two models of shadowing for nuclear PDFs ; the EKS model and the NDSG model. The uncertainties given, containing statistical and systematical error, are corresponding to one standard deviation.

Collins and Sivers asymmetries for pions and kaons in muon-deuteron DIS

The COMPASS collaboration Alekseev, M. ; Alexakhin, V.Yu. ; Alexandrov, Yu. ; et al.

Phys.Lett.B 673 (2009) 127-135, 2009.

Inspire Record 779473 DOI 10.17182/hepdata.48532

The measurements of the Collins and Sivers asymmetries of identified hadrons produced in deep-inelastic scattering of 160 GeV/c muons on a transversely polarised 6LiD target at COMPASS are presented. The results for charged pions and charged and neutral kaons correspond to all data available, which were collected from 2002 to 2004. For all final state particles both the Collins and Sivers asymmetries turn out to be small, compatible with zero within the statistical errors, in line with the previously published results for not identified charged hadrons, and with the expected cancellation between the u- and d-quark contributions.

1 data table match query

The Collins and Sivers asymmetry as a function of X for 'LEADING' positive kaons from the 2003-2004 data.. Errors are statistical only.

Common suppression pattern of eta and pi0 mesons at high transverse momentum in Au + Au collisions at s(NN)**(1/2) = 200-GeV.

The PHENIX collaboration Adler, S.S. ; Afanasiev, S. ; Aidala, C. ; et al.

Phys.Rev.Lett. 96 (2006) 202301, 2006.

Inspire Record 709321 DOI 10.17182/hepdata.141855

Inclusive transverse momentum spectra of eta mesons have been measured within p_T = 2-10 GeV/c at mid-rapidity by the PHENIX experiment in Au+Au collisions at sqrt(s_NN) = 200 GeV. In central Au+Au the eta yields are significantly suppressed compared to peripheral Au+Au, d+Au and p+p yields scaled by the corresponding number of nucleon-nucleon collisions. The magnitude, centrality and p_T dependence of the suppression is common, within errors, for eta and pi^0. The ratio of eta to pi^0 spectra at high p_T amounts to 0.40 < R_eta/pi^0 < 0.48 for the three systems in agreement with the world average measured in hadronic and nuclear reactions and, at large scaled momentum, in e^+e^- collisions.

1 data table match query

$R_{AA} (p_T)$ measured in central Au+Au at $\sqrt{s_{NN}}$ = 200 GeV for $\eta, \pi^0$, and direct $\gamma$. Points with no error are the upper limit. Point-to-point uncorrelated uncertainties are called "sys-uncorr", point-to-point correlated uncertainties are called "sys-corr", and normalization uncertainties are called "sys-norm."

rivet Analysis
Consistent measurements of alpha(s) from precise oriented event shape distributions.

The DELPHI collaboration Abreu, P. ; Adam, W. ; Adye, T. ; et al.

Eur.Phys.J.C 14 (2000) 557-584, 2000.

Inspire Record 522656 DOI 10.17182/hepdata.13245

An updated analysis using about 1.5 million events recorded at $\sqrt{s} = M_Z$ with the DELPHI detector in 1994 is presented. Eighteen infrared and collinear safe event shape observables are measured as a function of the polar angle of the thrust axis. The data are compared to theoretical calculations in ${\cal O} (\alpha_s^2)$ including the event orientation. A combined fit of $\alpha_s$ and of the renormalization scale $x_{\mu}$ in $\cal O(\alpha_s^2$) yields an excellent description of the high statistics data. The weighted average from 18 observables including quark mass effects and correlations is $\alpha_s(M_Z^2) = 0.1174 \pm 0.0026$. The final result, derived from the jet cone energy fraction, the observable with the smallest theoretical and experimental uncertainty, is $\alpha_s(M_Z^2) = 0.1180 \pm 0.0006 (exp.) \pm 0.0013 (hadr.) \pm 0.0008 (scale) \pm 0.0007 (mass)$. Further studies include an $\alpha_s$ determination using theoretical predictions in the next-to-leading log approximation (NLLA), matched NLLA and $\cal O(\alpha_s^2$) predictions as well as theoretically motivated optimized scale setting methods. The influence of higher order contributions was also investigated by using the method of Pad\'{e} approximants. Average $\alpha_s$ values derived from the different approaches are in good agreement.

1 data table match query

Energy Energy Correlation EEC.

Constraining the ${\rm\overline{K}N}$ coupled channel dynamics using femtoscopic correlations at the LHC

The ALICE collaboration Acharya, Shreyasi ; Adamova, Dagmar ; Adler, Alexander ; et al.

Eur.Phys.J.C 83 (2023) 340, 2023.

Inspire Record 2088954 DOI 10.17182/hepdata.132766

The interaction of $\rm{K}^{-}$ with protons is characterised by the presence of several coupled channels, systems like ${\rm \overline{K}^0}$n and $\pi\Sigma$ with a similar mass and the same quantum numbers as the $\rm{K}^{-}$p state. The strengths of these couplings to the $\rm{K}^{-}$p system are of crucial importance for the understanding of the nature of the $\Lambda(1405)$ resonance and of the attractive $\rm{K}^{-}$p strong interaction. In this article, we present measurements of the $\rm{K}^{-}$p correlation functions in relative momentum space obtained in pp collisions at $\sqrt{s}~=~13$ TeV, in p-Pb collisions at $\sqrt{s_{\mathrm{NN}}}~=~5.02$ TeV, and (semi)peripheral Pb-Pb collisions at $\sqrt{s_{\mathrm{NN}}}~=~5.02$ TeV. The emitting source size, composed of a core radius anchored to the $\rm{K}^{+}$p correlation and of a resonance halo specific to each particle pair, varies between 1 and 2 fm in these collision systems. The strength and the effects of the ${\rm \overline{K}^0}$n and $\pi\Sigma$ inelastic channels on the measured $\rm{K}^{-}$p correlation function are investigated in the different colliding systems by comparing the data with state-of-the-art models of chiral potentials. A novel approach to determine the conversion weights $\omega$, necessary to quantify the amount of produced inelastic channels in the correlation function, is presented. In this method, particle yields are estimated from thermal model predictions, and their kinematic distribution from blast-wave fits to measured data. The comparison of chiral potentials to the measured $\rm{K}^{-}$p interaction indicates that, while the $\pi\Sigma-\rm{K}^{-}$p dynamics is well reproduced by the model, the coupling to the ${\rm \overline{K}^0}$n channel in the model is currently underestimated.

1 data table match query

K$^+$p (K$^+$p $\oplus$ K$^-\overline{\mathrm p}$) correlation function in Pb-Pb collisions at $\sqrt{s_{\mathrm{NN}}} = 5.02$ TeV (60-70%).

Constraints on spin-0 dark matter mediators and invisible Higgs decays using ATLAS 13 TeV $pp$ collision data with two top quarks and missing transverse momentum in the final state

The ATLAS collaboration Aad, Georges ; Abbott, Braden Keim ; Abbott, D.C. ; et al.

Eur.Phys.J.C 83 (2023) 503, 2023.

Inspire Record 2180393 DOI 10.17182/hepdata.129623

This paper presents a statistical combination of searches targeting final states with two top quarks and invisible particles, characterised by the presence of zero, one or two leptons, at least one jet originating from a $b$-quark and missing transverse momentum. The analyses are searches for phenomena beyond the Standard Model consistent with the direct production of dark matter in $pp$ collisions at the LHC, using 139 fb$^{-\text{1}}$ of data collected with the ATLAS detector at a centre-of-mass energy of 13 TeV. The results are interpreted in terms of simplified dark matter models with a spin-0 scalar or pseudoscalar mediator particle. In addition, the results are interpreted in terms of upper limits on the Higgs boson invisible branching ratio, where the Higgs boson is produced according to the Standard Model in association with a pair of top quarks. For scalar (pseudoscalar) dark matter models, with all couplings set to unity, the statistical combination extends the mass range excluded by the best of the individual channels by 50 (25) GeV, excluding mediator masses up to 370 GeV. In addition, the statistical combination improves the expected coupling exclusion reach by 14% (24%), assuming a scalar (pseudoscalar) mediator mass of 10 GeV. An upper limit on the Higgs boson invisible branching ratio of 0.38 (0.30$^{+\text{0.13}}_{-\text{0.09}}$) is observed (expected) at 95% confidence level.

1 data table match query

Auxiliary Table 22

Cutflow for the reference point DM+$tW$ $m(a, \chi) = (10, 1)$ GeV in signal region SRTX. The column labelled 'weighted' shows the event yield including all correction factors applied to simulation, and is normalised to 139 fb$^{-1}$. A notable exception concerns the 'weighted' numbers in the first and the second row, labelled 'Total' and 'Filtered', which correspond to $\mathcal{L}\cdot\sigma$ and $\mathcal{L}\cdot\sigma\cdot\epsilon$ expected, respectively. The 'Skim' selection requires the $p_{\text{T}}$ of the leading four jets to be above (80, 60, 40, 40) GeV, the missing transverse momentum $E_{\text{T}}^{\text{miss}} > 140$ GeV, the missing momentum significance $\mathcal{S} > 8$, $\Delta\phi_{\min}(\vec{p}_{\text{T,1-4}},\vec{p}_{\text{T}}^{\text{miss}}) > 0.4$ and a lepton veto. The 'Orthogonalisation' selection is defined in the main body. In total 100000 raw MC events were generated prior to the specified cuts, with the column 'Unweighted yield' collecting the numbers after each cut.

Correlations between flow and transverse momentum in Xe+Xe and Pb+Pb collisions at the LHC with the ATLAS detector: a probe of the heavy-ion initial state and nuclear deformation

The ATLAS collaboration Aad, Georges ; Abbott, Braden Keim ; Abbott, D.C. ; et al.

Phys.Rev.C 107 (2023) 054910, 2023.

Inspire Record 2075412 DOI 10.17182/hepdata.139082

The correlations between flow harmonics $v_n$ for $n=2$, 3 and 4 and mean transverse momentum $[p_\mathrm{T}]$ in $^{129}$Xe+$^{129}$Xe and $^{208}$Pb+$^{208}$Pb collisions at $\sqrt{s_{\mathrm{NN}}}=5.44$ TeV and 5.02 TeV, respectively, are measured using charged particles with the ATLAS detector. The correlations are sensitive to the shape and size of the initial geometry, nuclear deformation, and initial momentum anisotropy. The effects from non-flow and centrality fluctuations are minimized, respectively, via a subevent cumulant method and event activity selection based on particle production in the very forward rapidity. The results show strong dependences on centrality, harmonic number $n$, $p_{\mathrm{T}}$ and pseudorapidity range. Current models describe qualitatively the overall centrality- and system-dependent trends but fail to quantitatively reproduce all the data. In the central collisions, where models generally show good agreement, the $v_2$-$[p_\mathrm{T}]$ correlations are sensitive to the triaxiality of the quadruple deformation. The comparison of model to the Pb+Pb and Xe+Xe data suggests that the $^{129}$Xe nucleus is a highly deformed triaxial ellipsoid that is neither a prolate nor an oblate shape. This provides strong evidence for a triaxial deformation of $^{129}$Xe nucleus using high-energy heavy-ion collision.

1 data table match query

$\rho_{3}$ Combined_subevent method, for Xe+Xe 5.44 TeV, $|\eta|$<2.5, 0.5< $p_{T}$ <5.0 GeV vs $\Sigma E_{T}$ based Centrality

rivet Analysis
Cross sections for the reactions $e^+ e^-\to K_S^0 K_L^0$, $K_S^0 K_L^0 \pi^+\pi^-$, $K_S^0 K_S^0 \pi^+\pi^-$, and $K_S^0 K_S^0 K^+K^-$ from events with initial-state radiation

The BaBar collaboration Lees, J.P. ; Poireau, V. ; Tisserand, V. ; et al.

Phys.Rev.D 89 (2014) 092002, 2014.

Inspire Record 1287920 DOI 10.17182/hepdata.64506

We study the processes $e^+ e^-\to K_S^0 K_L^0 \gamma$, $K_S^0 K_L^0 \pi^+\pi^-\gamma$, $K_S^0 K_S^0 \pi^+\pi^-\gamma$, and $K_S^0 K_S^0 K^+K^-\gamma$, where the photon is radiated from the initial state, providing cross section measurements for the hadronic states over a continuum of center-of-mass energies. The results are based on 469 fb$^{-1}$ of data collected with the BaBar detector at SLAC. We observe the $\phi(1020)$ resonance in the $K_S^0 K_L^0$ final state and measure the product of its electronic width and branching fraction with about 3% uncertainty. We present a measurement of the $e^+ e^-\to K_S^0 K_L^0 $ cross section in the energy range from 1.06 to 2.2 GeV and observe the production of a resonance at 1.67 GeV. We present the first measurements of the $e^+ e^-\to K_S^0 K_L^0 \pi^+\pi^-$, $K_S^0 K_S^0 \pi^+\pi^-$, and $K_S^0 K_S^0 K^+K^-$ cross sections, and study the intermediate resonance structures. We obtain the first observations of \jpsi decay to the $K_S^0 K_L^0 \pi^+\pi^-$, $K_S^0 K_S^0 \pi^+\pi^-$, and $K_S^0 K_S^0 K^+K^-$ final states.

1 data table match query

The product WIDTH(E+ E- --> J/PSI) * BR(J/PSI --> F2PRIME(1525) K+ K-) * BR(F2PRIME(1525) --> KS KS) and the J/PSI branching fraction.

rivet Analysis
Cross-section measurements for the production of a $Z$ boson in association with high-transverse-momentum jets in $pp$ collisions at $\sqrt{s} = 13$ TeV with the ATLAS detector

The ATLAS collaboration Aad, Georges ; Abbott, Braden Keim ; Abbott, D.C. ; et al.

JHEP 06 (2023) 080, 2023.

Inspire Record 2077570 DOI 10.17182/hepdata.114865

Cross-section measurements for a $Z$ boson produced in association with high-transverse-momentum jets ($p_{\mathrm{T}} \geq 100$ GeV) and decaying into a charged-lepton pair ($e^+e^-,\mu^+\mu^-$) are presented. The measurements are performed using proton-proton collisions at $\sqrt{s}=13$ TeV corresponding to an integrated luminosity of $139$ fb$^{-1}$ collected by the ATLAS experiment at the LHC. Measurements of angular correlations between the $Z$ boson and the closest jet are performed in events with at least one jet with $p_{\mathrm{T}} \geq 500$ GeV. Event topologies of particular interest are the collinear emission of a $Z$ boson in dijet events and a boosted $Z$ boson recoiling against a jet. Fiducial cross sections are compared with state-of-the-art theoretical predictions. The data are found to agree with next-to-next-to-leading-order predictions by NNLOjet and with the next-to-leading-order multi-leg generators MadGraph5_aMC@NLO and Sherpa.

1 data table match query

Systematic uncertainties for the jet multiplicity in the collinear region in Z($\to \ell^{+} \ell^{-}$) + high p$_{\mathrm{T}}$ jets events. The uncertainties are presented as a percentage of the measured cross-section for the upward variation of each source of uncertainty in each bin.

Deep inelastic inclusive and diffractive scattering at $Q^2$ values from 25 to 320 GeV$^2$ with the ZEUS forward plug calorimeter

The ZEUS collaboration Chekanov, S. ; Derrick, M. ; Magill, S. ; et al.

Nucl.Phys.B 800 (2008) 1-76, 2008.

Inspire Record 779854 DOI 10.17182/hepdata.11639

Deep inelastic scattering and its diffractive component, $ep \to e^{\prime}\gamma^* p \to e^{\prime}XN$, have been studied at HERA with the ZEUS detector using an integrated luminosity of 52.4 pb$^{-1}$. The $M_X$ method has been used to extract the diffractive contribution. A wide range in the centre-of-mass energy $W$ (37 -- 245 GeV), photon virtuality $Q^2$ (20 -- 450 GeV$^2$) and mass $M_X$ (0.28 -- 35 GeV) is covered. The diffractive cross section for $2 < M_X < 15$ GeV rises strongly with $W$, the rise becoming steeper as $Q^2$ increases. The data are also presented in terms of the diffractive structure function, $F^{\rm D(3)}_2$, of the proton. For fixed $Q^2$ and fixed $M_X$, $\xpom F^{\rm D(3)}_2$ shows a strong rise as $\xpom \to 0$, where $\xpom$ is the fraction of the proton momentum carried by the Pomeron. For Bjorken-$x < 1 \cdot 10^{-3}$, $\xpom F^{\rm D(3)}_2$ shows positive $\log Q^2$ scaling violations, while for $x \ge 5 \cdot 10^{-3}$ negative scaling violations are observed. The diffractive structure function is compatible with being leading twist. The data show that Regge factorisation is broken.

1 data table match query

Cross section for diffractive scattering GAMMA* P --> DD X where M(DD) < 2.3 GeV and M(X) = 1.2 GeV for Q**2 = 55 GeV**2.

Deep inelastic scattering with leading protons or large rapidity gaps at HERA

The ZEUS collaboration Chekanov, S. ; Derrick, M. ; Magill, S. ; et al.

Nucl.Phys.B 816 (2009) 1-61, 2009.

Inspire Record 804915 DOI 10.17182/hepdata.52860

The dissociation of virtual photons, $\gamma^{\star} p \to X p$, in events with a large rapidity gap between $X$ and the outgoing proton, as well as in events in which the leading proton was directly measured, has been studied with the ZEUS detector at HERA. The data cover photon virtualities $Q^2>2$ GeV$^2$ and $\gamma^{\star} p$ centre-of-mass energies $40<W<240$ GeV, with $M_X>2$ GeV, where $M_X$ is the mass of the hadronic final state, $X$. Leading protons were detected in the ZEUS leading proton spectrometer. The cross section is presented as a function of $t$, the squared four-momentum transfer at the proton vertex and $\Phi$, the azimuthal angle between the positron scattering plane and the proton scattering plane. It is also shown as a function of $Q^2$ and $\xpom$, the fraction of the proton's momentum carried by the diffractive exchange, as well as $\beta$, the Bjorken variable defined with respect to the diffractive exchange.

2 data tables match query

The reduced diffractive cross sections obtained from the LPS data as a function of X(NAME=POMERON) for Q**2 = 3.9 GeV**2 and ABS(T) = 0.19 to 0.55 GeV**2 for M(X) values of 3, 7, 15 and 30 GeV.

The reduced diffractive cross sections obtained from the LRG data as a function of X(NAME=POMERON) for Q**2 = 22 GeV**2 and M(X) values of 3, 6, 11, 19 and 32 GeV.

Delta(phi) Delta(eta) correlations in central Au + Au collisions at s(NN)**(1/2) = 200-GeV.

The STAR collaboration Adams, J. ; Aggarwal, M.M. ; Ahammed, Z. ; et al.

Phys.Rev.C 75 (2007) 034901, 2007.

Inspire Record 721060 DOI 10.17182/hepdata.102086

We report charged-particle pair correlation analyses in the space of Delta -phi (azimuth) and Delta -eta (pseudo-rapidity), for central Au + Au collisions at sqrt{s_{NN}} = 200 GeV in the STAR detector. The analysis involves unlike-sign charge pairs and like-sign charge pairs, which are transformed into charge-dependent (CD) signals and charge-independent (CI) signals. We present detailed parameterizations of the data. A model featuring dense gluonic hot spots as first proposed by van Hove predicts that the observables under investigation would have sensitivity to such a substructure should it occur, and the model also motivates selection of transverse momenta in the range 0.8 < p_t < 2.0$ GeV/c. Both CD and CI correlations of high statistical significance are observed and possible interpretations are discussed.

1 data table match query

Figure 3a (left panel)

FIG. 3: a) left side: Folded correlation data for unlike-sign charge pairs on $\Delta\phi$ and $\Delta\eta$ based on demonstrated symmetries in the data. This increases the statistics in a typical bin by a factor of four. Henceforth we will be dealing with folded data only. b) right side: Similar folded data for like-sign charge pairs.

Dielectron Azimuthal Anisotropy at mid-rapidity in Au+Au collisions at $\sqrt{s_{_{NN}}} = 200$ GeV

The STAR collaboration Adamczyk, L. ; Adkins, J.K. ; Agakishiev, G. ; et al.

Phys.Rev.C 90 (2014) 064904, 2014.

Inspire Record 1280745 DOI 10.17182/hepdata.96269

We report on the first measurement of the azimuthal anisotropy ($v_2$) of dielectrons ($e^{+}e^{-}$ pairs) at mid-rapidity from $\sqrt{s_{_{NN}}} = 200$ GeV Au+Au collisions with the STAR detector at RHIC, presented as a function of transverse momentum ($p_T$) for different invariant-mass regions. In the mass region $M_{ee}\!<1.1$ GeV/$c^2$ the dielectron $v_2$ measurements are found to be consistent with expectations from $\pi^{0}$, $\eta$, $\omega$ and $\phi$ decay contributions. In the mass region $1.1\!<M_{ee}\!<2.9$ GeV/$c^2$, the measured dielectron $v_2$ is consistent, within experimental uncertainties, with that from the $c\bar{c}$ contributions.

3 data tables match query

Figure 22 (exp. data)

The $p_T$-integrated dielectron $v_2$ as a function of $M_{ee}$ in minimum-bias Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

Figure 22 (hadron data)

The $v_2$ of hadrons $\pi$, $K$, $p$, $\phi$ and $\Lambda$ in minimum-bias Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV for the $\pi^0$ mass region.

Figure 22 (sim. data)

The $p_T$-integrated dielectron $v_2$ as a function of $M_{ee}$ in minimum-bias Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV, expected from the decays of $\pi^0$, $\eta$, $\omega$ and $\phi$ and from the $car{c}$ contribution.

Dielectron Mass Spectra from Au+Au Collisions at $\sqrt{s_{\rm NN}}$ = 200 GeV

The STAR collaboration Adamczyk, L. ; Adkins, J.K. ; Agakishiev, G. ; et al.

Phys.Rev.Lett. 113 (2014) 022301, 2014.

Inspire Record 1275614 DOI 10.17182/hepdata.95663

We report the STAR measurements of dielectron ($e^+e^-$) production at midrapidity ($|y_{ee}|<$1) in Au+Au collisions at $\sqrt{s_{\rm NN}}$ = 200\,GeV. The measurements are evaluated in different invariant mass regions with a focus on 0.30-0.76 ($\rho$-like), 0.76-0.80 ($\omega$-like), and 0.98-1.05 ($\phi$-like) GeV/$c^{2}$. The spectrum in the $\omega$-like and $\phi$-like regions can be well described by the hadronic cocktail simulation. In the $\rho$-like region, however, the vacuum $\rho$ spectral function cannot describe the shape of the dielectron excess. In this range, an enhancement of 1.77$\pm$0.11(stat.)$\pm$0.24(sys.)$\pm$0.33(cocktail) is determined with respect to the hadronic cocktail simulation that excludes the $\rho$ meson. The excess yield in the $\rho$-like region increases with the number of collision participants faster than the $\omega$ and $\phi$ yields. Theoretical models with broadened $\rho$ contributions through interactions with constituents in the hot QCD medium provide a consistent description of the dilepton mass spectra for the measurement presented here and the earlier data at the Super Proton Synchrotron energies.

1 data table match query

Integrated dielectron yields in the mass regions of 0.30-0.76 (rho-like), 0.76-0.80 (omega-like), and 0.98-1.05 (phi-like) GeV/c^2 compared to hadronic cocktails within the STAR acceptance as a function of centrality.

rivet Analysis
Differential $t\bar{t}$ cross-section measurements using boosted top quarks in the all-hadronic final state with 139 fb$^{-1}$ of ATLAS data

The ATLAS collaboration Aad, Georges ; Abbott, Braden Keim ; Abbott, D.C. ; et al.

JHEP 04 (2023) 080, 2023.

Inspire Record 2077575 DOI 10.17182/hepdata.115142

Measurements of single-, double-, and triple-differential cross-sections are presented for boosted top-quark pair-production in 13 $\text{TeV}$ proton-proton collisions recorded by the ATLAS detector at the LHC. The top quarks are observed through their hadronic decay and reconstructed as large-radius jets with the leading jet having transverse momentum ($p_{\text{T}}$) greater than 500 GeV. The observed data are unfolded to remove detector effects. The particle-level cross-section, multiplied by the $t\bar{t} \rightarrow W W b \bar{b}$ branching fraction and measured in a fiducial phase space defined by requiring the leading and second-leading jets to have $p_{\text{T}} > 500$ GeV and $p_{\text{T}} > 350$ GeV, respectively, is $331 \pm 3 \text{(stat.)} \pm 39 \text{(syst.)}$ fb. This is approximately 20$\%$ lower than the prediction of $398^{+48}_{-49}$ fb by Powheg+Pythia 8 with next-to-leading-order (NLO) accuracy but consistent within the theoretical uncertainties. Results are also presented at the parton level, where the effects of top-quark decay, parton showering, and hadronization are removed such that they can be compared with fixed-order next-to-next-to-leading-order (NNLO) calculations. The parton-level cross-section, measured in a fiducial phase space similar to that at particle level, is $1.94 \pm 0.02 \text{(stat.)} \pm 0.25 \text{(syst.)}$ pb. This agrees with the NNLO prediction of $1.96^{+0.02}_{-0.17}$ pb. Reasonable agreement with the differential cross-sections is found for most NLO models, while the NNLO calculations are generally in better agreement with the data. The differential cross-sections are interpreted using a Standard Model effective field-theory formalism and limits are set on Wilson coefficients of several four-fermion operators.

2 data tables match query

Table of contents

- - - - - - - - Overview of HEPData Record - - - - - - - - <br/><br/> <b>Fiducial phase space definitions:</b><br/> <i>Particle level:</i> <ul> <li> NLEP = 0, E or MU, PT > 25 GeV, ABS ETA < 2.5 <li> NJETS >= 2, R = 1.0, 350 GeV < PT < 3000 GeV, ABS ETA < 2, M > 50 GeV <li> NJETS >= 1, R = 1.0, 500 GeV < PT < 3000 GeV, ABS ETA < 2, M > 50 GeV <li> T1, MIN ( ABS ( M - 172.5 GeV ) ), candidate JETS with PT > 500 GeV <li> T2, MIN ( ABS ( M - 172.5 GeV ) ), remaining candidate JETS with PT > 350 GeV <li> T1 and T2, 122.5 GeV < M < 222.5 GeV, ghost-matched B-HAD with PT > 5 GeV </ul><br/> <i>Parton level:</i> <ul> <li> PT_T1 > 500 GeV, PT_T2 > 350 GeV </ul><br/> <b>Particle level:</b><br/> <u>1D:</u><br/> Spectra: <ul><br/> <li>SIG (<a href="115142?table=Table 1">Table 1</a>) <li>DSIG/DPT_TOP (<a href="115142?table=Table 2">Table 2</a>) <li>DSIG/DABS_Y_TOP (<a href="115142?table=Table 3">Table 3</a>) <li>DSIG/DPT_T1 (<a href="115142?table=Table 4">Table 4</a>) <li>DSIG/DABS_Y_T1 (<a href="115142?table=Table 5">Table 5</a>) <li>DSIG/DPT_T2 (<a href="115142?table=Table 6">Table 6</a>) <li>DSIG/DABS_Y_T2 (<a href="115142?table=Table 7">Table 7</a>) <li>DSIG/DM_TTBAR (<a href="115142?table=Table 8">Table 8</a>) <li>DSIG/DPT_TTBAR (<a href="115142?table=Table 9">Table 9</a>) <li>DSIG/DABS_Y_TTBAR (<a href="115142?table=Table 10">Table 10</a>) <li>DSIG/DCHI_TTBAR (<a href="115142?table=Table 11">Table 11</a>) <li>DSIG/DABS_Y_BOOST (<a href="115142?table=Table 12">Table 12</a>) <li>DSIG/DABS_POUT (<a href="115142?table=Table 13">Table 13</a>) <li>DSIG/DABS_DPHI_TTBAR (<a href="115142?table=Table 14">Table 14</a>) <li>DSIG/DHT_TTBAR (<a href="115142?table=Table 15">Table 15</a>) <li>DSIG/DABS_COS_THETA_STAR (<a href="115142?table=Table 16">Table 16</a>) <li>1/SIG*DSIG/DPT_TOP (<a href="115142?table=Table 74">Table 74</a>) <li>1/SIG*DSIG/DABS_Y_TOP (<a href="115142?table=Table 75">Table 75</a>) <li>1/SIG*DSIG/DPT_T1 (<a href="115142?table=Table 76">Table 76</a>) <li>1/SIG*DSIG/DABS_Y_T1 (<a href="115142?table=Table 77">Table 77</a>) <li>1/SIG*DSIG/DPT_T2 (<a href="115142?table=Table 78">Table 78</a>) <li>1/SIG*DSIG/DABS_Y_T2 (<a href="115142?table=Table 79">Table 79</a>) <li>1/SIG*DSIG/DM_TTBAR (<a href="115142?table=Table 80">Table 80</a>) <li>1/SIG*DSIG/DPT_TTBAR (<a href="115142?table=Table 81">Table 81</a>) <li>1/SIG*DSIG/DABS_Y_TTBAR (<a href="115142?table=Table 82">Table 82</a>) <li>1/SIG*DSIG/DCHI_TTBAR (<a href="115142?table=Table 83">Table 83</a>) <li>1/SIG*DSIG/DABS_Y_BOOST (<a href="115142?table=Table 84">Table 84</a>) <li>1/SIG*DSIG/DABS_POUT (<a href="115142?table=Table 85">Table 85</a>) <li>1/SIG*DSIG/DABS_DPHI_TTBAR (<a href="115142?table=Table 86">Table 86</a>) <li>1/SIG*DSIG/DHT_TTBAR (<a href="115142?table=Table 87">Table 87</a>) <li>1/SIG*DSIG/DABS_COS_THETA_STAR (<a href="115142?table=Table 88">Table 88</a>) </ul><br/> Covariances: <ul><br/> <li>DSIG/DPT_TOP (<a href="115142?table=Table 291">Table 291</a>) <li>DSIG/DABS_Y_TOP (<a href="115142?table=Table 292">Table 292</a>) <li>DSIG/DPT_T1 (<a href="115142?table=Table 293">Table 293</a>) <li>DSIG/DABS_Y_T1 (<a href="115142?table=Table 294">Table 294</a>) <li>DSIG/DPT_T2 (<a href="115142?table=Table 295">Table 295</a>) <li>DSIG/DABS_Y_T2 (<a href="115142?table=Table 296">Table 296</a>) <li>DSIG/DM_TTBAR (<a href="115142?table=Table 297">Table 297</a>) <li>DSIG/DPT_TTBAR (<a href="115142?table=Table 298">Table 298</a>) <li>DSIG/DABS_Y_TTBAR (<a href="115142?table=Table 299">Table 299</a>) <li>DSIG/DCHI_TTBAR (<a href="115142?table=Table 300">Table 300</a>) <li>DSIG/DABS_Y_BOOST (<a href="115142?table=Table 301">Table 301</a>) <li>DSIG/DABS_POUT (<a href="115142?table=Table 302">Table 302</a>) <li>DSIG/DABS_DPHI_TTBAR (<a href="115142?table=Table 303">Table 303</a>) <li>DSIG/DHT_TTBAR (<a href="115142?table=Table 304">Table 304</a>) <li>DSIG/DABS_COS_THETA_STAR (<a href="115142?table=Table 305">Table 305</a>) <li>1/SIG*DSIG/DPT_TOP (<a href="115142?table=Table 471">Table 471</a>) <li>1/SIG*DSIG/DABS_Y_TOP (<a href="115142?table=Table 472">Table 472</a>) <li>1/SIG*DSIG/DPT_T1 (<a href="115142?table=Table 473">Table 473</a>) <li>1/SIG*DSIG/DABS_Y_T1 (<a href="115142?table=Table 474">Table 474</a>) <li>1/SIG*DSIG/DPT_T2 (<a href="115142?table=Table 475">Table 475</a>) <li>1/SIG*DSIG/DABS_Y_T2 (<a href="115142?table=Table 476">Table 476</a>) <li>1/SIG*DSIG/DM_TTBAR (<a href="115142?table=Table 477">Table 477</a>) <li>1/SIG*DSIG/DPT_TTBAR (<a href="115142?table=Table 478">Table 478</a>) <li>1/SIG*DSIG/DABS_Y_TTBAR (<a href="115142?table=Table 479">Table 479</a>) <li>1/SIG*DSIG/DCHI_TTBAR (<a href="115142?table=Table 480">Table 480</a>) <li>1/SIG*DSIG/DABS_Y_BOOST (<a href="115142?table=Table 481">Table 481</a>) <li>1/SIG*DSIG/DABS_POUT (<a href="115142?table=Table 482">Table 482</a>) <li>1/SIG*DSIG/DABS_DPHI_TTBAR (<a href="115142?table=Table 483">Table 483</a>) <li>1/SIG*DSIG/DHT_TTBAR (<a href="115142?table=Table 484">Table 484</a>) <li>1/SIG*DSIG/DABS_COS_THETA_STAR (<a href="115142?table=Table 485">Table 485</a>) </ul><br/> <u>2D:</u><br/> Spectra: <ul><br/> <li>D2SIG/DPT_T2/DPT_T1 (0.50 TeV < PT_T1 < 0.55 TeV) (<a href="115142?table=Table 17">Table 17</a>) <li>D2SIG/DPT_T2/DPT_T1 (0.55 TeV < PT_T1 < 0.60 TeV) (<a href="115142?table=Table 18">Table 18</a>) <li>D2SIG/DPT_T2/DPT_T1 (0.60 TeV < PT_T1 < 0.75 TeV) (<a href="115142?table=Table 19">Table 19</a>) <li>D2SIG/DPT_T2/DPT_T1 (0.75 TeV < PT_T1 < 2.00 TeV) (<a href="115142?table=Table 20">Table 20</a>) <li>D2SIG/DABS_Y_T2/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 21">Table 21</a>) <li>D2SIG/DABS_Y_T2/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 22">Table 22</a>) <li>D2SIG/DABS_Y_T2/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 23">Table 23</a>) <li>D2SIG/DABS_Y_T2/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 24">Table 24</a>) <li>D2SIG/DPT_T1/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 25">Table 25</a>) <li>D2SIG/DPT_T1/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 26">Table 26</a>) <li>D2SIG/DPT_T1/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 27">Table 27</a>) <li>D2SIG/DPT_T1/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 28">Table 28</a>) <li>D2SIG/DPT_T2/DABS_Y_T2 (0.0 < ABS_Y_T2 < 0.2) (<a href="115142?table=Table 29">Table 29</a>) <li>D2SIG/DPT_T2/DABS_Y_T2 (0.2 < ABS_Y_T2 < 0.5) (<a href="115142?table=Table 30">Table 30</a>) <li>D2SIG/DPT_T2/DABS_Y_T2 (0.5 < ABS_Y_T2 < 1.0) (<a href="115142?table=Table 31">Table 31</a>) <li>D2SIG/DPT_T2/DABS_Y_T2 (1.0 < ABS_Y_T2 < 2.0) (<a href="115142?table=Table 32">Table 32</a>) <li>D2SIG/DPT_TTBAR/DPT_T1 (0.500 TeV < PT_T1 < 0.550 TeV) (<a href="115142?table=Table 33">Table 33</a>) <li>D2SIG/DPT_TTBAR/DPT_T1 (0.550 TeV < PT_T1 < 0.625 TeV) (<a href="115142?table=Table 34">Table 34</a>) <li>D2SIG/DPT_TTBAR/DPT_T1 (0.625 TeV < PT_T1 < 0.750 TeV) (<a href="115142?table=Table 35">Table 35</a>) <li>D2SIG/DPT_TTBAR/DPT_T1 (0.750 TeV < PT_T1 < 2.000 TeV) (<a href="115142?table=Table 36">Table 36</a>) <li>D2SIG/DM_TTBAR/DPT_T1 (0.500 TeV < PT_T1 < 0.550 TeV) (<a href="115142?table=Table 37">Table 37</a>) <li>D2SIG/DM_TTBAR/DPT_T1 (0.550 TeV < PT_T1 < 0.625 TeV) (<a href="115142?table=Table 38">Table 38</a>) <li>D2SIG/DM_TTBAR/DPT_T1 (0.625 TeV < PT_T1 < 0.750 TeV) (<a href="115142?table=Table 39">Table 39</a>) <li>D2SIG/DM_TTBAR/DPT_T1 (0.750 TeV < PT_T1 < 2.000 TeV) (<a href="115142?table=Table 40">Table 40</a>) <li>D2SIG/DPT_T1/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 41">Table 41</a>) <li>D2SIG/DPT_T1/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 42">Table 42</a>) <li>D2SIG/DPT_T1/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 43">Table 43</a>) <li>D2SIG/DPT_T1/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 44">Table 44</a>) <li>D2SIG/DABS_Y_T1/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 45">Table 45</a>) <li>D2SIG/DABS_Y_T1/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 46">Table 46</a>) <li>D2SIG/DABS_Y_T1/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 47">Table 47</a>) <li>D2SIG/DABS_Y_T1/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 48">Table 48</a>) <li>D2SIG/DM_TTBAR/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 49">Table 49</a>) <li>D2SIG/DM_TTBAR/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 50">Table 50</a>) <li>D2SIG/DM_TTBAR/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 51">Table 51</a>) <li>D2SIG/DM_TTBAR/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 52">Table 52</a>) <li>D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 53">Table 53</a>) <li>D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 54">Table 54</a>) <li>D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 55">Table 55</a>) <li>D2SIG/DM_TTBAR/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 56">Table 56</a>) <li>D2SIG/DM_TTBAR/PT_TTBAR (0.00 TeV < PT_TTBAR < 0.10 TeV) (<a href="115142?table=Table 57">Table 57</a>) <li>D2SIG/DM_TTBAR/PT_TTBAR (0.10 TeV < PT_TTBAR < 0.20 TeV) (<a href="115142?table=Table 58">Table 58</a>) <li>D2SIG/DM_TTBAR/PT_TTBAR (0.20 TeV < PT_TTBAR < 0.35 TeV) (<a href="115142?table=Table 59">Table 59</a>) <li>D2SIG/DM_TTBAR/PT_TTBAR (0.35 TeV < PT_TTBAR < 1.00 TeV) (<a href="115142?table=Table 60">Table 60</a>) <li>D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 61">Table 61</a>) <li>D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 62">Table 62</a>) <li>D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 63">Table 63</a>) <li>D2SIG/PT_TTBAR/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 64">Table 64</a>) <li>1/SIG*D2SIG/DPT_T2/DPT_T1 (0.50 TeV < PT_T1 < 0.55 TeV) (<a href="115142?table=Table 89">Table 89</a>) <li>1/SIG*D2SIG/DPT_T2/DPT_T1 (0.55 TeV < PT_T1 < 0.60 TeV) (<a href="115142?table=Table 90">Table 90</a>) <li>1/SIG*D2SIG/DPT_T2/DPT_T1 (0.60 TeV < PT_T1 < 0.75 TeV) (<a href="115142?table=Table 91">Table 91</a>) <li>1/SIG*D2SIG/DPT_T2/DPT_T1 (0.75 TeV < PT_T1 < 2.00 TeV) (<a href="115142?table=Table 92">Table 92</a>) <li>1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 93">Table 93</a>) <li>1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 94">Table 94</a>) <li>1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 95">Table 95</a>) <li>1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 96">Table 96</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 97">Table 97</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 98">Table 98</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 99">Table 99</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 100">Table 100</a>) <li>1/SIG*D2SIG/DPT_T2/DABS_Y_T2 (0.0 < ABS_Y_T2 < 0.2) (<a href="115142?table=Table 101">Table 101</a>) <li>1/SIG*D2SIG/DPT_T2/DABS_Y_T2 (0.2 < ABS_Y_T2 < 0.5) (<a href="115142?table=Table 102">Table 102</a>) <li>1/SIG*D2SIG/DPT_T2/DABS_Y_T2 (0.5 < ABS_Y_T2 < 1.0) (<a href="115142?table=Table 103">Table 103</a>) <li>1/SIG*D2SIG/DPT_T2/DABS_Y_T2 (1.0 < ABS_Y_T2 < 2.0) (<a href="115142?table=Table 104">Table 104</a>) <li>1/SIG*D2SIG/DPT_TTBAR/DPT_T1 (0.500 TeV < PT_T1 < 0.550 TeV) (<a href="115142?table=Table 105">Table 105</a>) <li>1/SIG*D2SIG/DPT_TTBAR/DPT_T1 (0.550 TeV < PT_T1 < 0.625 TeV) (<a href="115142?table=Table 106">Table 106</a>) <li>1/SIG*D2SIG/DPT_TTBAR/DPT_T1 (0.625 TeV < PT_T1 < 0.750 TeV) (<a href="115142?table=Table 107">Table 107</a>) <li>1/SIG*D2SIG/DPT_TTBAR/DPT_T1 (0.750 TeV < PT_T1 < 2.000 TeV) (<a href="115142?table=Table 108">Table 108</a>) <li>1/SIG*D2SIG/DM_TTBAR/DPT_T1 (0.500 TeV < PT_T1 < 0.550 TeV) (<a href="115142?table=Table 109">Table 109</a>) <li>1/SIG*D2SIG/DM_TTBAR/DPT_T1 (0.550 TeV < PT_T1 < 0.625 TeV) (<a href="115142?table=Table 110">Table 110</a>) <li>1/SIG*D2SIG/DM_TTBAR/DPT_T1 (0.625 TeV < PT_T1 < 0.750 TeV) (<a href="115142?table=Table 111">Table 111</a>) <li>1/SIG*D2SIG/DM_TTBAR/DPT_T1 (0.750 TeV < PT_T1 < 2.000 TeV) (<a href="115142?table=Table 112">Table 112</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 113">Table 113</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 114">Table 114</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 115">Table 115</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 116">Table 116</a>) <li>1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 117">Table 117</a>) <li>1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 118">Table 118</a>) <li>1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 119">Table 119</a>) <li>1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 120">Table 120</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 121">Table 121</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 122">Table 122</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 123">Table 123</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 124">Table 124</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 125">Table 125</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 126">Table 126</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 127">Table 127</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 128">Table 128</a>) <li>1/SIG*D2SIG/DM_TTBAR/PT_TTBAR (0.00 TeV < PT_TTBAR < 0.10 TeV) (<a href="115142?table=Table 129">Table 129</a>) <li>1/SIG*D2SIG/DM_TTBAR/PT_TTBAR (0.10 TeV < PT_TTBAR < 0.20 TeV) (<a href="115142?table=Table 130">Table 130</a>) <li>1/SIG*D2SIG/DM_TTBAR/PT_TTBAR (0.20 TeV < PT_TTBAR < 0.35 TeV) (<a href="115142?table=Table 131">Table 131</a>) <li>1/SIG*D2SIG/DM_TTBAR/PT_TTBAR (0.35 TeV < PT_TTBAR < 1.00 TeV) (<a href="115142?table=Table 132">Table 132</a>) <li>1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 133">Table 133</a>) <li>1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 134">Table 134</a>) <li>1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 135">Table 135</a>) <li>1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 136">Table 136</a>) </ul><br/> Covariances: <ul><br/> <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 306">Table 306</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 307">Table 307</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 308">Table 308</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 309">Table 309</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 310">Table 310</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 311">Table 311</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 312">Table 312</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 313">Table 313</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 314">Table 314</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 315">Table 315</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 316">Table 316</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 317">Table 317</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 318">Table 318</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 319">Table 319</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 320">Table 320</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 321">Table 321</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 322">Table 322</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 323">Table 323</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 324">Table 324</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 325">Table 325</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 326">Table 326</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 327">Table 327</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 328">Table 328</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 329">Table 329</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 330">Table 330</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 331">Table 331</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 332">Table 332</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 333">Table 333</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 334">Table 334</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 335">Table 335</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 1st bins of ABS_Y_T2 (<a href="115142?table=Table 336">Table 336</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 2nd bins of ABS_Y_T2 (<a href="115142?table=Table 337">Table 337</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 338">Table 338</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 339">Table 339</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 2nd bins of ABS_Y_T2 (<a href="115142?table=Table 340">Table 340</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 341">Table 341</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 342">Table 342</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 3rd and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 343">Table 343</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 3rd and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 344">Table 344</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 4th and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 345">Table 345</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 346">Table 346</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 347">Table 347</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 348">Table 348</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 349">Table 349</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 350">Table 350</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 351">Table 351</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 352">Table 352</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 353">Table 353</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 354">Table 354</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 355">Table 355</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 356">Table 356</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 357">Table 357</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 358">Table 358</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 359">Table 359</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 360">Table 360</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 361">Table 361</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 362">Table 362</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 363">Table 363</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 364">Table 364</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 365">Table 365</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 366">Table 366</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 367">Table 367</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 368">Table 368</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 369">Table 369</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 370">Table 370</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 371">Table 371</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 372">Table 372</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 373">Table 373</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 374">Table 374</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 375">Table 375</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 376">Table 376</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 377">Table 377</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 378">Table 378</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 379">Table 379</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 380">Table 380</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 381">Table 381</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 382">Table 382</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 383">Table 383</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 384">Table 384</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 385">Table 385</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 386">Table 386</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 387">Table 387</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 388">Table 388</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 389">Table 389</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 390">Table 390</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 391">Table 391</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 392">Table 392</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 393">Table 393</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 394">Table 394</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 395">Table 395</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 396">Table 396</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 397">Table 397</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 398">Table 398</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 399">Table 399</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 400">Table 400</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 401">Table 401</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 402">Table 402</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 403">Table 403</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 404">Table 404</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 405">Table 405</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 1st bins of PT_TTBAR (<a href="115142?table=Table 406">Table 406</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 2nd bins of PT_TTBAR (<a href="115142?table=Table 407">Table 407</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 3rd bins of PT_TTBAR (<a href="115142?table=Table 408">Table 408</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 4th bins of PT_TTBAR (<a href="115142?table=Table 409">Table 409</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 2nd bins of PT_TTBAR (<a href="115142?table=Table 410">Table 410</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 3rd bins of PT_TTBAR (<a href="115142?table=Table 411">Table 411</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 4th bins of PT_TTBAR (<a href="115142?table=Table 412">Table 412</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 3rd and 3rd bins of PT_TTBAR (<a href="115142?table=Table 413">Table 413</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 3rd and 4th bins of PT_TTBAR (<a href="115142?table=Table 414">Table 414</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 4th and 4th bins of PT_TTBAR (<a href="115142?table=Table 415">Table 415</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 416">Table 416</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 417">Table 417</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 418">Table 418</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 419">Table 419</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 420">Table 420</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 421">Table 421</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 422">Table 422</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 423">Table 423</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 424">Table 424</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 425">Table 425</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 486">Table 486</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 487">Table 487</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 488">Table 488</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 489">Table 489</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 490">Table 490</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 491">Table 491</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 492">Table 492</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 493">Table 493</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 494">Table 494</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 495">Table 495</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 496">Table 496</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 497">Table 497</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 498">Table 498</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 499">Table 499</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 500">Table 500</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 501">Table 501</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 502">Table 502</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 503">Table 503</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 504">Table 504</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 505">Table 505</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 506">Table 506</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 507">Table 507</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 508">Table 508</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 509">Table 509</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 510">Table 510</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 511">Table 511</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 512">Table 512</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 513">Table 513</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 514">Table 514</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 515">Table 515</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 1st bins of ABS_Y_T2 (<a href="115142?table=Table 516">Table 516</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 2nd bins of ABS_Y_T2 (<a href="115142?table=Table 517">Table 517</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 518">Table 518</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 519">Table 519</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 2nd bins of ABS_Y_T2 (<a href="115142?table=Table 520">Table 520</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 521">Table 521</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 522">Table 522</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 3rd and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 523">Table 523</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 3rd and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 524">Table 524</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 4th and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 525">Table 525</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 526">Table 526</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 527">Table 527</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 528">Table 528</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 529">Table 529</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 530">Table 530</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 531">Table 531</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 532">Table 532</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 533">Table 533</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 534">Table 534</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 535">Table 535</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 536">Table 536</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 537">Table 537</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 538">Table 538</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 539">Table 539</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 540">Table 540</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 541">Table 541</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 542">Table 542</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 543">Table 543</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 544">Table 544</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 545">Table 545</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 546">Table 546</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 547">Table 547</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 548">Table 548</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 549">Table 549</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 550">Table 550</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 551">Table 551</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 552">Table 552</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 553">Table 553</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 554">Table 554</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 555">Table 555</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 556">Table 556</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 557">Table 557</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 558">Table 558</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 559">Table 559</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 560">Table 560</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 561">Table 561</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 562">Table 562</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 563">Table 563</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 564">Table 564</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 565">Table 565</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 566">Table 566</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 567">Table 567</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 568">Table 568</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 569">Table 569</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 570">Table 570</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 571">Table 571</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 572">Table 572</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 573">Table 573</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 574">Table 574</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 575">Table 575</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 576">Table 576</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 577">Table 577</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 578">Table 578</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 579">Table 579</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 580">Table 580</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 581">Table 581</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 582">Table 582</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 583">Table 583</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 584">Table 584</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 585">Table 585</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 1st bins of PT_TTBAR (<a href="115142?table=Table 586">Table 586</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 2nd bins of PT_TTBAR (<a href="115142?table=Table 587">Table 587</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 3rd bins of PT_TTBAR (<a href="115142?table=Table 588">Table 588</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 4th bins of PT_TTBAR (<a href="115142?table=Table 589">Table 589</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 2nd bins of PT_TTBAR (<a href="115142?table=Table 590">Table 590</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 3rd bins of PT_TTBAR (<a href="115142?table=Table 591">Table 591</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 4th bins of PT_TTBAR (<a href="115142?table=Table 592">Table 592</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 3rd and 3rd bins of PT_TTBAR (<a href="115142?table=Table 593">Table 593</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 3rd and 4th bins of PT_TTBAR (<a href="115142?table=Table 594">Table 594</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 4th and 4th bins of PT_TTBAR (<a href="115142?table=Table 595">Table 595</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 596">Table 596</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 597">Table 597</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 598">Table 598</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 599">Table 599</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 600">Table 600</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 601">Table 601</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 602">Table 602</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 603">Table 603</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 604">Table 604</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 605">Table 605</a>) </ul><br/> <u>3D:</u><br/> Spectra: <ul><br/> <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 65">Table 65</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 66">Table 66</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 67">Table 67</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 68">Table 68</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 69">Table 69</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 70">Table 70</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 71">Table 71</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 72">Table 72</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 73">Table 73</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 137">Table 137</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 138">Table 138</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 139">Table 139</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 140">Table 140</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 141">Table 141</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 142">Table 142</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 143">Table 143</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 144">Table 144</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 145">Table 145</a>) </ul><br/> Covariances: <ul><br/> <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 426">Table 426</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 427">Table 427</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 428">Table 428</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 429">Table 429</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 430">Table 430</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 431">Table 431</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 432">Table 432</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 433">Table 433</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 434">Table 434</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 435">Table 435</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 436">Table 436</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 437">Table 437</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 438">Table 438</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 439">Table 439</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 440">Table 440</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 441">Table 441</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 442">Table 442</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 443">Table 443</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 444">Table 444</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 445">Table 445</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 446">Table 446</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 447">Table 447</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 448">Table 448</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 449">Table 449</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 450">Table 450</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 451">Table 451</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 452">Table 452</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 453">Table 453</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 454">Table 454</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 455">Table 455</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 456">Table 456</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 457">Table 457</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 458">Table 458</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 459">Table 459</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 460">Table 460</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 461">Table 461</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 462">Table 462</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 463">Table 463</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 464">Table 464</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 465">Table 465</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 466">Table 466</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 467">Table 467</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 468">Table 468</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 469">Table 469</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 470">Table 470</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 606">Table 606</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 607">Table 607</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 608">Table 608</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 609">Table 609</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 610">Table 610</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 611">Table 611</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 612">Table 612</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 613">Table 613</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 614">Table 614</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 615">Table 615</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 616">Table 616</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 617">Table 617</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 618">Table 618</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 619">Table 619</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 620">Table 620</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 621">Table 621</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 622">Table 622</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 623">Table 623</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 624">Table 624</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 625">Table 625</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 626">Table 626</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 627">Table 627</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 628">Table 628</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 629">Table 629</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 630">Table 630</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 631">Table 631</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 632">Table 632</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 633">Table 633</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 634">Table 634</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 635">Table 635</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 636">Table 636</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 637">Table 637</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 638">Table 638</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 639">Table 639</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 640">Table 640</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 641">Table 641</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 642">Table 642</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 643">Table 643</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 644">Table 644</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 645">Table 645</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 646">Table 646</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 647">Table 647</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 648">Table 648</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 649">Table 649</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 650">Table 650</a>) </ul><br/> <b>Parton level:</b><br/> <u>1D:</u><br/> Spectra: <ul><br/> <li>SIG (<a href="115142?table=Table 146">Table 146</a>) <li>DSIG/DPT_TOP (<a href="115142?table=Table 147">Table 147</a>) <li>DSIG/DABS_Y_TOP (<a href="115142?table=Table 148">Table 148</a>) <li>DSIG/DPT_T1 (<a href="115142?table=Table 149">Table 149</a>) <li>DSIG/DABS_Y_T1 (<a href="115142?table=Table 150">Table 150</a>) <li>DSIG/DPT_T2 (<a href="115142?table=Table 151">Table 151</a>) <li>DSIG/DABS_Y_T2 (<a href="115142?table=Table 152">Table 152</a>) <li>DSIG/DM_TTBAR (<a href="115142?table=Table 153">Table 153</a>) <li>DSIG/DPT_TTBAR (<a href="115142?table=Table 154">Table 154</a>) <li>DSIG/DABS_Y_TTBAR (<a href="115142?table=Table 155">Table 155</a>) <li>DSIG/DCHI_TTBAR (<a href="115142?table=Table 156">Table 156</a>) <li>DSIG/DABS_Y_BOOST (<a href="115142?table=Table 157">Table 157</a>) <li>DSIG/DABS_POUT (<a href="115142?table=Table 158">Table 158</a>) <li>DSIG/DABS_DPHI_TTBAR (<a href="115142?table=Table 159">Table 159</a>) <li>DSIG/DHT_TTBAR (<a href="115142?table=Table 160">Table 160</a>) <li>DSIG/DABS_COS_THETA_STAR (<a href="115142?table=Table 161">Table 161</a>) <li>1/SIG*DSIG/DPT_TOP (<a href="115142?table=Table 219">Table 219</a>) <li>1/SIG*DSIG/DABS_Y_TOP (<a href="115142?table=Table 220">Table 220</a>) <li>1/SIG*DSIG/DPT_T1 (<a href="115142?table=Table 221">Table 221</a>) <li>1/SIG*DSIG/DABS_Y_T1 (<a href="115142?table=Table 222">Table 222</a>) <li>1/SIG*DSIG/DPT_T2 (<a href="115142?table=Table 223">Table 223</a>) <li>1/SIG*DSIG/DABS_Y_T2 (<a href="115142?table=Table 224">Table 224</a>) <li>1/SIG*DSIG/DM_TTBAR (<a href="115142?table=Table 225">Table 225</a>) <li>1/SIG*DSIG/DPT_TTBAR (<a href="115142?table=Table 226">Table 226</a>) <li>1/SIG*DSIG/DABS_Y_TTBAR (<a href="115142?table=Table 227">Table 227</a>) <li>1/SIG*DSIG/DCHI_TTBAR (<a href="115142?table=Table 228">Table 228</a>) <li>1/SIG*DSIG/DABS_Y_BOOST (<a href="115142?table=Table 229">Table 229</a>) <li>1/SIG*DSIG/DABS_POUT (<a href="115142?table=Table 230">Table 230</a>) <li>1/SIG*DSIG/DABS_DPHI_TTBAR (<a href="115142?table=Table 231">Table 231</a>) <li>1/SIG*DSIG/DHT_TTBAR (<a href="115142?table=Table 232">Table 232</a>) <li>1/SIG*DSIG/DABS_COS_THETA_STAR (<a href="115142?table=Table 233">Table 233</a>) </ul><br/> Covariances: <ul><br/> <li>DSIG/DPT_TOP (<a href="115142?table=Table 651">Table 651</a>) <li>DSIG/DABS_Y_TOP (<a href="115142?table=Table 652">Table 652</a>) <li>DSIG/DPT_T1 (<a href="115142?table=Table 653">Table 653</a>) <li>DSIG/DABS_Y_T1 (<a href="115142?table=Table 654">Table 654</a>) <li>DSIG/DPT_T2 (<a href="115142?table=Table 655">Table 655</a>) <li>DSIG/DABS_Y_T2 (<a href="115142?table=Table 656">Table 656</a>) <li>DSIG/DM_TTBAR (<a href="115142?table=Table 657">Table 657</a>) <li>DSIG/DPT_TTBAR (<a href="115142?table=Table 658">Table 658</a>) <li>DSIG/DABS_Y_TTBAR (<a href="115142?table=Table 659">Table 659</a>) <li>DSIG/DCHI_TTBAR (<a href="115142?table=Table 660">Table 660</a>) <li>DSIG/DABS_Y_BOOST (<a href="115142?table=Table 661">Table 661</a>) <li>DSIG/DABS_POUT (<a href="115142?table=Table 662">Table 662</a>) <li>DSIG/DABS_DPHI_TTBAR (<a href="115142?table=Table 663">Table 663</a>) <li>DSIG/DHT_TTBAR (<a href="115142?table=Table 664">Table 664</a>) <li>DSIG/DABS_COS_THETA_STAR (<a href="115142?table=Table 665">Table 665</a>) <li>1/SIG*DSIG/DPT_TOP (<a href="115142?table=Table 831">Table 831</a>) <li>1/SIG*DSIG/DABS_Y_TOP (<a href="115142?table=Table 832">Table 832</a>) <li>1/SIG*DSIG/DPT_T1 (<a href="115142?table=Table 833">Table 833</a>) <li>1/SIG*DSIG/DABS_Y_T1 (<a href="115142?table=Table 834">Table 834</a>) <li>1/SIG*DSIG/DPT_T2 (<a href="115142?table=Table 835">Table 835</a>) <li>1/SIG*DSIG/DABS_Y_T2 (<a href="115142?table=Table 836">Table 836</a>) <li>1/SIG*DSIG/DM_TTBAR (<a href="115142?table=Table 837">Table 837</a>) <li>1/SIG*DSIG/DPT_TTBAR (<a href="115142?table=Table 838">Table 838</a>) <li>1/SIG*DSIG/DABS_Y_TTBAR (<a href="115142?table=Table 839">Table 839</a>) <li>1/SIG*DSIG/DCHI_TTBAR (<a href="115142?table=Table 840">Table 840</a>) <li>1/SIG*DSIG/DABS_Y_BOOST (<a href="115142?table=Table 841">Table 841</a>) <li>1/SIG*DSIG/DABS_POUT (<a href="115142?table=Table 842">Table 842</a>) <li>1/SIG*DSIG/DABS_DPHI_TTBAR (<a href="115142?table=Table 843">Table 843</a>) <li>1/SIG*DSIG/DHT_TTBAR (<a href="115142?table=Table 844">Table 844</a>) <li>1/SIG*DSIG/DABS_COS_THETA_STAR (<a href="115142?table=Table 845">Table 845</a>) </ul><br/> <u>2D:</u><br/> Spectra: <ul><br/> <li>D2SIG/DPT_T2/DPT_T1 (0.50 TeV < PT_T1 < 0.550 TeV) (<a href="115142?table=Table 162">Table 162</a>) <li>D2SIG/DPT_T2/DPT_T1 (0.55 TeV < PT_T1 < 0.60 TeV) (<a href="115142?table=Table 163">Table 163</a>) <li>D2SIG/DPT_T2/DPT_T1 (0.60 TeV < PT_T1 < 0.75 TeV) (<a href="115142?table=Table 164">Table 164</a>) <li>D2SIG/DPT_T2/DPT_T1 (0.75 TeV < PT_T1 < 2.00 TeV) (<a href="115142?table=Table 165">Table 165</a>) <li>D2SIG/DABS_Y_T2/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 166">Table 166</a>) <li>D2SIG/DABS_Y_T2/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 167">Table 167</a>) <li>D2SIG/DABS_Y_T2/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 168">Table 168</a>) <li>D2SIG/DABS_Y_T2/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 169">Table 169</a>) <li>D2SIG/DPT_T1/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 170">Table 170</a>) <li>D2SIG/DPT_T1/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 171">Table 171</a>) <li>D2SIG/DPT_T1/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 172">Table 172</a>) <li>D2SIG/DPT_T1/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 173">Table 173</a>) <li>D2SIG/DPT_T2/DABS_Y_T2 (0.0 < ABS_Y_T2 < 0.2) (<a href="115142?table=Table 174">Table 174</a>) <li>D2SIG/DPT_T2/DABS_Y_T2 (0.2 < ABS_Y_T2 < 0.5) (<a href="115142?table=Table 175">Table 175</a>) <li>D2SIG/DPT_T2/DABS_Y_T2 (0.5 < ABS_Y_T2 < 1.0) (<a href="115142?table=Table 176">Table 176</a>) <li>D2SIG/DPT_T2/DABS_Y_T2 (1.0 < ABS_Y_T2 < 2.0) (<a href="115142?table=Table 177">Table 177</a>) <li>D2SIG/DPT_TTBAR/DPT_T1 (0.500 TeV < PT_T1 < 0.550 TeV) (<a href="115142?table=Table 178">Table 178</a>) <li>D2SIG/DPT_TTBAR/DPT_T1 (0.550 TeV < PT_T1 < 0.625 TeV) (<a href="115142?table=Table 179">Table 179</a>) <li>D2SIG/DPT_TTBAR/DPT_T1 (0.625 TeV < PT_T1 < 0.750 TeV) (<a href="115142?table=Table 180">Table 180</a>) <li>D2SIG/DPT_TTBAR/DPT_T1 (0.750 TeV < PT_T1 < 2.000 TeV) (<a href="115142?table=Table 181">Table 181</a>) <li>D2SIG/DM_TTBAR/DPT_T1 (0.500 TeV < PT_T1 < 0.550 TeV) (<a href="115142?table=Table 182">Table 182</a>) <li>D2SIG/DM_TTBAR/DPT_T1 (0.550 TeV < PT_T1 < 0.625 TeV) (<a href="115142?table=Table 183">Table 183</a>) <li>D2SIG/DM_TTBAR/DPT_T1 (0.625 TeV < PT_T1 < 0.750 TeV) (<a href="115142?table=Table 184">Table 184</a>) <li>D2SIG/DM_TTBAR/DPT_T1 (0.750 TeV < PT_T1 < 2.000 TeV) (<a href="115142?table=Table 185">Table 185</a>) <li>D2SIG/DPT_T1/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 186">Table 186</a>) <li>D2SIG/DPT_T1/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 187">Table 187</a>) <li>D2SIG/DPT_T1/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 188">Table 188</a>) <li>D2SIG/DPT_T1/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 189">Table 189</a>) <li>D2SIG/DY_T1/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 190">Table 190</a>) <li>D2SIG/DY_T1/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 191">Table 191</a>) <li>D2SIG/DY_T1/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 192">Table 192</a>) <li>D2SIG/DY_T1/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 193">Table 193</a>) <li>D2SIG/DM_TTBAR/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 194">Table 194</a>) <li>D2SIG/DM_TTBAR/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 195">Table 195</a>) <li>D2SIG/DM_TTBAR/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 196">Table 196</a>) <li>D2SIG/DM_TTBAR/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 197">Table 197</a>) <li>D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 198">Table 198</a>) <li>D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 199">Table 199</a>) <li>D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 200">Table 200</a>) <li>D2SIG/DM_TTBAR/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 201">Table 201</a>) <li>D2SIG/DM_TTBAR/PT_TTBAR (0.00 TeV < PT_TTBAR < 0.10 TeV) (<a href="115142?table=Table 202">Table 202</a>) <li>D2SIG/DM_TTBAR/PT_TTBAR (0.10 TeV < PT_TTBAR < 0.20 TeV) (<a href="115142?table=Table 203">Table 203</a>) <li>D2SIG/DM_TTBAR/PT_TTBAR (0.20 TeV < PT_TTBAR < 0.35 TeV) (<a href="115142?table=Table 204">Table 204</a>) <li>D2SIG/DM_TTBAR/PT_TTBAR (0.35 TeV < PT_TTBAR < 1.00 TeV) (<a href="115142?table=Table 205">Table 205</a>) <li>D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 206">Table 206</a>) <li>D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 207">Table 207</a>) <li>D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 208">Table 208</a>) <li>D2SIG/PT_TTBAR/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 209">Table 209</a>) <li>1/SIG*D2SIG/DPT_T2/DPT_T1 (0.50 TeV < PT_T1 < 0.55 TeV) (<a href="115142?table=Table 234">Table 234</a>) <li>1/SIG*D2SIG/DPT_T2/DPT_T1 (0.55 TeV < PT_T1 < 0.60 TeV) (<a href="115142?table=Table 235">Table 235</a>) <li>1/SIG*D2SIG/DPT_T2/DPT_T1 (0.60 TeV < PT_T1 < 0.75 TeV) (<a href="115142?table=Table 236">Table 236</a>) <li>1/SIG*D2SIG/DPT_T2/DPT_T1 (0.75 TeV < PT_T1 < 2.00 TeV) (<a href="115142?table=Table 237">Table 237</a>) <li>1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 238">Table 238</a>) <li>1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 239">Table 239</a>) <li>1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 240">Table 240</a>) <li>1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 241">Table 241</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 242">Table 242</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 243">Table 243</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 244">Table 244</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 245">Table 245</a>) <li>1/SIG*D2SIG/DPT_T2/DABS_Y_T2 (0.0 < ABS_Y_T2 < 0.2) (<a href="115142?table=Table 246">Table 246</a>) <li>1/SIG*D2SIG/DPT_T2/DABS_Y_T2 (0.2 < ABS_Y_T2 < 0.5) (<a href="115142?table=Table 247">Table 247</a>) <li>1/SIG*D2SIG/DPT_T2/DABS_Y_T2 (0.5 < ABS_Y_T2 < 1.0) (<a href="115142?table=Table 248">Table 248</a>) <li>1/SIG*D2SIG/DPT_T2/DABS_Y_T2 (1.0 < ABS_Y_T2 < 2.0) (<a href="115142?table=Table 249">Table 249</a>) <li>1/SIG*D2SIG/DPT_TTBAR/DPT_T1 (0.500 TeV < PT_T1 < 0.550 TeV) (<a href="115142?table=Table 250">Table 250</a>) <li>1/SIG*D2SIG/DPT_TTBAR/DPT_T1 (0.550 TeV < PT_T1 < 0.625 TeV) (<a href="115142?table=Table 251">Table 251</a>) <li>1/SIG*D2SIG/DPT_TTBAR/DPT_T1 (0.625 TeV < PT_T1 < 0.750 TeV) (<a href="115142?table=Table 252">Table 252</a>) <li>1/SIG*D2SIG/DPT_TTBAR/DPT_T1 (0.750 TeV < PT_T1 < 2.000 TeV) (<a href="115142?table=Table 253">Table 253</a>) <li>1/SIG*D2SIG/DM_TTBAR/DPT_T1 (0.500 TeV < PT_T1 < 0.550 TeV) (<a href="115142?table=Table 254">Table 254</a>) <li>1/SIG*D2SIG/DM_TTBAR/DPT_T1 (0.550 TeV < PT_T1 < 0.625 TeV) (<a href="115142?table=Table 255">Table 255</a>) <li>1/SIG*D2SIG/DM_TTBAR/DPT_T1 (0.625 TeV < PT_T1 < 0.750 TeV) (<a href="115142?table=Table 256">Table 256</a>) <li>1/SIG*D2SIG/DM_TTBAR/DPT_T1 (0.750 TeV < PT_T1 < 2.000 TeV) (<a href="115142?table=Table 257">Table 257</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 258">Table 258</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 259">Table 259</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 260">Table 260</a>) <li>1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 261">Table 261</a>) <li>1/SIG*D2SIG/DY_T1/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 262">Table 262</a>) <li>1/SIG*D2SIG/DY_T1/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 263">Table 263</a>) <li>1/SIG*D2SIG/DY_T1/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 264">Table 264</a>) <li>1/SIG*D2SIG/DY_T1/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 265">Table 265</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 (0.0 < ABS_Y_T1 < 0.2) (<a href="115142?table=Table 266">Table 266</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 (0.2 < ABS_Y_T1 < 0.5) (<a href="115142?table=Table 267">Table 267</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 (0.5 < ABS_Y_T1 < 1.0) (<a href="115142?table=Table 268">Table 268</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 (1.0 < ABS_Y_T1 < 2.0) (<a href="115142?table=Table 269">Table 269</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 270">Table 270</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 271">Table 271</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 272">Table 272</a>) <li>1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 273">Table 273</a>) <li>1/SIG*D2SIG/DM_TTBAR/PT_TTBAR (0.00 TeV < PT_TTBAR < 0.10 TeV) (<a href="115142?table=Table 274">Table 274</a>) <li>1/SIG*D2SIG/DM_TTBAR/PT_TTBAR (0.10 TeV < PT_TTBAR < 0.20 TeV) (<a href="115142?table=Table 275">Table 275</a>) <li>1/SIG*D2SIG/DM_TTBAR/PT_TTBAR (0.20 TeV < PT_TTBAR < 0.35 TeV) (<a href="115142?table=Table 276">Table 276</a>) <li>1/SIG*D2SIG/DM_TTBAR/PT_TTBAR (0.35 TeV < PT_TTBAR < 1.00 TeV) (<a href="115142?table=Table 277">Table 277</a>) <li>1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.0 < ABS_Y_TTBAR < 0.2) (<a href="115142?table=Table 278">Table 278</a>) <li>1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.2 < ABS_Y_TTBAR < 0.5) (<a href="115142?table=Table 279">Table 279</a>) <li>1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR (0.5 < ABS_Y_TTBAR < 1.0) (<a href="115142?table=Table 280">Table 280</a>) <li>1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR (1.0 < ABS_Y_TTBAR < 2.0) (<a href="115142?table=Table 281">Table 281</a>) </ul><br/> Covariances: <ul><br/> <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 666">Table 666</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 667">Table 667</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 668">Table 668</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 669">Table 669</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 670">Table 670</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 671">Table 671</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 672">Table 672</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 673">Table 673</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 674">Table 674</a>) <li>Matrix for D2SIG/DPT_T2/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 675">Table 675</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 676">Table 676</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 677">Table 677</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 678">Table 678</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 679">Table 679</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 680">Table 680</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 681">Table 681</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 682">Table 682</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 683">Table 683</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 684">Table 684</a>) <li>Matrix for D2SIG/DABS_Y_T2/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 685">Table 685</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 686">Table 686</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 687">Table 687</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 688">Table 688</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 689">Table 689</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 690">Table 690</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 691">Table 691</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 692">Table 692</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 693">Table 693</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 694">Table 694</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 695">Table 695</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 1st bins of ABS_Y_T2 (<a href="115142?table=Table 696">Table 696</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 2nd bins of ABS_Y_T2 (<a href="115142?table=Table 697">Table 697</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 698">Table 698</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 699">Table 699</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 2nd bins of ABS_Y_T2 (<a href="115142?table=Table 700">Table 700</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 701">Table 701</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 702">Table 702</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 3rd and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 703">Table 703</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 3rd and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 704">Table 704</a>) <li>Matrix for D2SIG/DPT_T2/DABS_Y_T2 between the 4th and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 705">Table 705</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 706">Table 706</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 707">Table 707</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 708">Table 708</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 709">Table 709</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 710">Table 710</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 711">Table 711</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 712">Table 712</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 713">Table 713</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 714">Table 714</a>) <li>Matrix for D2SIG/DPT_TTBAR/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 715">Table 715</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 716">Table 716</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 717">Table 717</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 718">Table 718</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 719">Table 719</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 720">Table 720</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 721">Table 721</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 722">Table 722</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 723">Table 723</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 724">Table 724</a>) <li>Matrix for D2SIG/DM_TTBAR/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 725">Table 725</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 726">Table 726</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 727">Table 727</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 728">Table 728</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 729">Table 729</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 730">Table 730</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 731">Table 731</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 732">Table 732</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 733">Table 733</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 734">Table 734</a>) <li>Matrix for D2SIG/DPT_T1/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 735">Table 735</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 736">Table 736</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 737">Table 737</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 738">Table 738</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 739">Table 739</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 740">Table 740</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 741">Table 741</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 742">Table 742</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 743">Table 743</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 744">Table 744</a>) <li>Matrix for D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 745">Table 745</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 746">Table 746</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 747">Table 747</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 748">Table 748</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 749">Table 749</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 750">Table 750</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 751">Table 751</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 752">Table 752</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 753">Table 753</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 754">Table 754</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 755">Table 755</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 756">Table 756</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 757">Table 757</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 758">Table 758</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 759">Table 759</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 760">Table 760</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 761">Table 761</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 762">Table 762</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 763">Table 763</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 764">Table 764</a>) <li>Matrix for D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 765">Table 765</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 1st bins of PT_TTBAR (<a href="115142?table=Table 766">Table 766</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 2nd bins of PT_TTBAR (<a href="115142?table=Table 767">Table 767</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 3rd bins of PT_TTBAR (<a href="115142?table=Table 768">Table 768</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 4th bins of PT_TTBAR (<a href="115142?table=Table 769">Table 769</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 2nd bins of PT_TTBAR (<a href="115142?table=Table 770">Table 770</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 3rd bins of PT_TTBAR (<a href="115142?table=Table 771">Table 771</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 4th bins of PT_TTBAR (<a href="115142?table=Table 772">Table 772</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 3rd and 3rd bins of PT_TTBAR (<a href="115142?table=Table 773">Table 773</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 3rd and 4th bins of PT_TTBAR (<a href="115142?table=Table 774">Table 774</a>) <li>Matrix for D2SIG/DM_TTBAR/PT_TTBAR between the 4th and 4th bins of PT_TTBAR (<a href="115142?table=Table 775">Table 775</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 776">Table 776</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 777">Table 777</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 778">Table 778</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 779">Table 779</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 780">Table 780</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 781">Table 781</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 782">Table 782</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 783">Table 783</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 784">Table 784</a>) <li>Matrix for D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 785">Table 785</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 846">Table 846</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 847">Table 847</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 848">Table 848</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 849">Table 849</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 850">Table 850</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 851">Table 851</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 852">Table 852</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 853">Table 853</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 854">Table 854</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 855">Table 855</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 856">Table 856</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 857">Table 857</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 858">Table 858</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 859">Table 859</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 860">Table 860</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 861">Table 861</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 862">Table 862</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 863">Table 863</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 864">Table 864</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T2/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 865">Table 865</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 866">Table 866</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 867">Table 867</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 868">Table 868</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 869">Table 869</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 870">Table 870</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 871">Table 871</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 872">Table 872</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 873">Table 873</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 874">Table 874</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 875">Table 875</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 1st bins of ABS_Y_T2 (<a href="115142?table=Table 876">Table 876</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 2nd bins of ABS_Y_T2 (<a href="115142?table=Table 877">Table 877</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 878">Table 878</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 1st and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 879">Table 879</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 2nd bins of ABS_Y_T2 (<a href="115142?table=Table 880">Table 880</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 881">Table 881</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 2nd and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 882">Table 882</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 3rd and 3rd bins of ABS_Y_T2 (<a href="115142?table=Table 883">Table 883</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 3rd and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 884">Table 884</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T2/DABS_Y_T2 between the 4th and 4th bins of ABS_Y_T2 (<a href="115142?table=Table 885">Table 885</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 886">Table 886</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 887">Table 887</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 888">Table 888</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 889">Table 889</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 890">Table 890</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 891">Table 891</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 892">Table 892</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 893">Table 893</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 894">Table 894</a>) <li>Matrix for 1/SIG*D2SIG/DPT_TTBAR/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 895">Table 895</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 1st and 1st bins of PT_T1 (<a href="115142?table=Table 896">Table 896</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 1st and 2nd bins of PT_T1 (<a href="115142?table=Table 897">Table 897</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 1st and 3rd bins of PT_T1 (<a href="115142?table=Table 898">Table 898</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 1st and 4th bins of PT_T1 (<a href="115142?table=Table 899">Table 899</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 2nd bins of PT_T1 (<a href="115142?table=Table 900">Table 900</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 3rd bins of PT_T1 (<a href="115142?table=Table 901">Table 901</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 2nd and 4th bins of PT_T1 (<a href="115142?table=Table 902">Table 902</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 3rd and 3rd bins of PT_T1 (<a href="115142?table=Table 903">Table 903</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 3rd and 4th bins of PT_T1 (<a href="115142?table=Table 904">Table 904</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DPT_T1 between the 4th and 4th bins of PT_T1 (<a href="115142?table=Table 905">Table 905</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 906">Table 906</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 907">Table 907</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 908">Table 908</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 909">Table 909</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 910">Table 910</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 911">Table 911</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 912">Table 912</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 913">Table 913</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 914">Table 914</a>) <li>Matrix for 1/SIG*D2SIG/DPT_T1/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 915">Table 915</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 916">Table 916</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 917">Table 917</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 918">Table 918</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 919">Table 919</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 920">Table 920</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 921">Table 921</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 922">Table 922</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 923">Table 923</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 924">Table 924</a>) <li>Matrix for 1/SIG*D2SIG/DABS_Y_T1/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 925">Table 925</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 1st bins of ABS_Y_T1 (<a href="115142?table=Table 926">Table 926</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 927">Table 927</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 928">Table 928</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 1st and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 929">Table 929</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 2nd bins of ABS_Y_T1 (<a href="115142?table=Table 930">Table 930</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 931">Table 931</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 2nd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 932">Table 932</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 3rd and 3rd bins of ABS_Y_T1 (<a href="115142?table=Table 933">Table 933</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 3rd and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 934">Table 934</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_T1 between the 4th and 4th bins of ABS_Y_T1 (<a href="115142?table=Table 935">Table 935</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 936">Table 936</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 937">Table 937</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 938">Table 938</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 939">Table 939</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 940">Table 940</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 941">Table 941</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 942">Table 942</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 943">Table 943</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 944">Table 944</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 945">Table 945</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 1st bins of PT_TTBAR (<a href="115142?table=Table 946">Table 946</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 2nd bins of PT_TTBAR (<a href="115142?table=Table 947">Table 947</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 3rd bins of PT_TTBAR (<a href="115142?table=Table 948">Table 948</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 1st and 4th bins of PT_TTBAR (<a href="115142?table=Table 949">Table 949</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 2nd bins of PT_TTBAR (<a href="115142?table=Table 950">Table 950</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 3rd bins of PT_TTBAR (<a href="115142?table=Table 951">Table 951</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 2nd and 4th bins of PT_TTBAR (<a href="115142?table=Table 952">Table 952</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 3rd and 3rd bins of PT_TTBAR (<a href="115142?table=Table 953">Table 953</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 3rd and 4th bins of PT_TTBAR (<a href="115142?table=Table 954">Table 954</a>) <li>Matrix for 1/SIG*D2SIG/DM_TTBAR/PT_TTBAR between the 4th and 4th bins of PT_TTBAR (<a href="115142?table=Table 955">Table 955</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 1st bins of ABS_Y_TTBAR (<a href="115142?table=Table 956">Table 956</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 957">Table 957</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 958">Table 958</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 1st and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 959">Table 959</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 2nd bins of ABS_Y_TTBAR (<a href="115142?table=Table 960">Table 960</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 961">Table 961</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 2nd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 962">Table 962</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 3rd and 3rd bins of ABS_Y_TTBAR (<a href="115142?table=Table 963">Table 963</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 3rd and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 964">Table 964</a>) <li>Matrix for 1/SIG*D2SIG/PT_TTBAR/DABS_Y_TTBAR between the 4th and 4th bins of ABS_Y_TTBAR (<a href="115142?table=Table 965">Table 965</a>) </ul><br/> <u>3D:</u><br/> Spectra: <ul><br/> <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 210">Table 210</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 211">Table 211</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 212">Table 212</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 213">Table 213</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 214">Table 214</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 215">Table 215</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 216">Table 216</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 217">Table 217</a>) <li>D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 218">Table 218</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 282">Table 282</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 283">Table 283</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.0 < ABS_Y_TTBAR < 0.3, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 284">Table 284</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 285">Table 285</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 286">Table 286</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.3 < ABS_Y_TTBAR < 0.9, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 287">Table 287</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 0.9 TeV < M_TTBAR < 1.2 TeV) (<a href="115142?table=Table 288">Table 288</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 1.2 TeV < M_TTBAR < 1.5 TeV) (<a href="115142?table=Table 289">Table 289</a>) <li>1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR (0.9 < ABS_Y_TTBAR < 2.0, 1.5 TeV < M_TTBAR < 4.0 TeV) (<a href="115142?table=Table 290">Table 290</a>) </ul><br/> Covariances: <ul><br/> <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 786">Table 786</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 787">Table 787</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 788">Table 788</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 789">Table 789</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 790">Table 790</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 791">Table 791</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 792">Table 792</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 793">Table 793</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 794">Table 794</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 795">Table 795</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 796">Table 796</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 797">Table 797</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 798">Table 798</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 799">Table 799</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 800">Table 800</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 801">Table 801</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 802">Table 802</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 803">Table 803</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 804">Table 804</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 805">Table 805</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 806">Table 806</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 807">Table 807</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 808">Table 808</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 809">Table 809</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 810">Table 810</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 811">Table 811</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 812">Table 812</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 813">Table 813</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 814">Table 814</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 815">Table 815</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 816">Table 816</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 817">Table 817</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 818">Table 818</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 819">Table 819</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 820">Table 820</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 821">Table 821</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 822">Table 822</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 823">Table 823</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 824">Table 824</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 825">Table 825</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 826">Table 826</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 827">Table 827</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 828">Table 828</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 829">Table 829</a>) <li>Matrix for D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 830">Table 830</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 966">Table 966</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 967">Table 967</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 968">Table 968</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 969">Table 969</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 970">Table 970</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 971">Table 971</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 972">Table 972</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 973">Table 973</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 974">Table 974</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 975">Table 975</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 976">Table 976</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 977">Table 977</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 978">Table 978</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 979">Table 979</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 980">Table 980</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 981">Table 981</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 982">Table 982</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 983">Table 983</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 984">Table 984</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 985">Table 985</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 986">Table 986</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 987">Table 987</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 988">Table 988</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (1st, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 989">Table 989</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 990">Table 990</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 991">Table 991</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 992">Table 992</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 993">Table 993</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 994">Table 994</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 995">Table 995</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 996">Table 996</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 997">Table 997</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 998">Table 998</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 999">Table 999</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1000">Table 1000</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1001">Table 1001</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1002">Table 1002</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1003">Table 1003</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (2nd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1004">Table 1004</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1005">Table 1005</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1006">Table 1006</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 1st) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1007">Table 1007</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1008">Table 1008</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 2nd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1009">Table 1009</a>) <li>Matrix for 1/SIG*D3SIG/DPT_T1/DABS_Y_TTBAR/DM_TTBAR between the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) and the (3rd, 3rd) bin of (ABS_Y_TTBAR, M_TTBAR) (<a href="115142?table=Table 1010">Table 1010</a>) </ul><br/>

$|{y}^{t,1}|\otimes |{y}^{t,2}|$ absolute differential cross-section at particle level, for 0.2 < $|{y}^{t,1}|$ < 0.5.

Direct photon production in d+Au collisions at sqrt(s_NN)=200 GeV

The PHENIX collaboration Adare, A. ; Adler, S.S. ; Afanasiev, S. ; et al.

Phys.Rev.C 87 (2013) 054907, 2013.

Inspire Record 1126017 DOI 10.17182/hepdata.142660

Direct photons have been measured in sqrt(s_NN)=200 GeV d+Au collisions at midrapidity. A wide p_T range is covered by measurements of nearly-real virtual photons (1<p_T<6 GeV/c) and real photons (5<p_T<16 GeV/c). The invariant yield of the direct photons in d+Au collisions over the scaled p+p cross section is consistent with unity. Theoretical calculations assuming standard cold nuclear matter effects describe the data well for the entire p_T range. This indicates that the large enhancement of direct photons observed in Au+Au collisions for 1.0<p_T<2.5 GeV/c is due to a source other than the initial-state nuclear effects.

1 data table match query

$R_{dA}$ ($d$+Au data/scaled $p+p$ fit). Nuclear modification factor for $d$+Au, $R_{dA}$, as a function of $p_{T}$ . The closed and open symbols show the results from the virtual- and real-photon measurements, respectively. The values in the table are equal to this mean value. The bars and bands represent the point-to-point (ptp.) and $p_{T}$-correlated (cor.) uncertainties, respectively. The box on the right shows the uncertainty of $T_{dA}$ for $d$+Au. The curves indicate the theoretical calculations [24] with different combinations of the CNM effects such as the Cronin enhancement, isospin effect, nuclear shadowing and initial state energy loss.

Direct virtual photon production in Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV

The STAR collaboration Adamczyk, L. ; Adkins, J.K. ; Agakishiev, G. ; et al.

Phys.Lett.B 770 (2017) 451-458, 2017.

Inspire Record 1474129 DOI 10.17182/hepdata.77495

We report the direct virtual photon invariant yields in the transverse momentum ranges $1\!<\!p_{T}\!<\!3$ GeV/$c$ and $5\!<\!p_T\!<\!10$ GeV/$c$ at mid-rapidity derived from the dielectron invariant mass continuum region $0.10<M_{ee}<0.28$ GeV/$c^{2}$ for 0-80\% minimum-bias Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV. A clear excess in the invariant yield compared to the number-of-binary-collisions ($N_{bin}$) scaled $p+p$ reference is observed in the $p_T$ range $1\!<\!p_{T}\!<\!3$ GeV/$c$. For $p_T\!>6$ GeV/$c$ the production follows $N_{bin}$ scaling. Model calculations with contributions from thermal radiation and initial hard parton scattering are consistent within uncertainties with the direct virtual photon invariant yield.

1 data table match query

Direct virtual photon total yield in 1.5-3.0GeV.

Elliptic flow of identified hadrons in Au + Au collisions at s(NN)**(1/2) = 200-GeV.

The PHENIX collaboration Adler, S.S. ; Afanasiev, S. ; Aidala, C. ; et al.

Phys.Rev.Lett. 91 (2003) 182301, 2003.

Inspire Record 619061 DOI 10.17182/hepdata.141613

The anisotropy parameter v_2, the second harmonic of the azimuthal particles distribution, has been measured with the PHENIX detector in Au+Au collisions at sqrt(s_NN) = 200 GeV for identified and inclusive charged particles at central rapidities (|eta| < 0.35) with respect to the reaction plane defined at high rapidities (|eta| = 3-4). The v_2 for all particles reaches a maximum at mid-centrality, and increases with p_T up to 2 GeV/c and then saturates or decreases slightly. Our results depart from hydrodynamically predicted behavior above 2 GeV/c. A quark coalescence model is also investigated.

1 data table match query

Transverse momentum dependence of $v_2$ for negative charged particle distributions at 0-20% centrality.

Elliptic flow of identified hadrons in Au+Au collisions at $\sqrt{s_{NN}}=$ 7.7--62.4 GeV

The STAR collaboration Adamczyk, L. ; Adkins, J.K. ; Agakishiev, G. ; et al.

Phys.Rev.C 88 (2013) 014902, 2013.

Inspire Record 1210464 DOI 10.17182/hepdata.102408

Measurements of the elliptic flow, $v_{2}$, of identified hadrons ($\pi^{\pm}$, $K^{\pm}$, $K_{s}^{0}$, $p$, $\bar{p}$, $\phi$, $\Lambda$, $\bar{\Lambda}$, $\Xi^{-}$, $\bar{\Xi}^{+}$, $\Omega^{-}$, $\bar{\Omega}^{+}$) in Au+Au collisions at $\sqrt{s_{NN}}=$ 7.7, 11.5, 19.6, 27, 39 and 62.4 GeV are presented. The measurements were done at mid-rapidity using the Time Projection Chamber and the Time-of-Flight detectors of the STAR experiment during the Beam Energy Scan program at RHIC. A significant difference in the $v_{2}$ values for particles and the corresponding anti-particles was observed at all transverse momenta for the first time. The difference increases with decreasing center-of-mass energy, $\sqrt{s_{NN}}$ (or increasing baryon chemical potential, $\mu_{B}$) and is larger for the baryons as compared to the mesons. This implies that particles and anti-particles are no longer consistent with the universal number-of-constituent quark (NCQ) scaling of $v_{2}$ that was observed at $\sqrt{s_{NN}}=$ 200 GeV. However, for the group of particles NCQ scaling at $(m_{T}-m_{0})/n_{q}>$ 0.4 GeV/$c^{2}$ is not violated within $\pm$10%. The $v_{2}$ values for $\phi$ mesons at 7.7 and 11.5 GeV are approximately two standard deviations from the trend defined by the other hadrons at the highest measured $p_{T}$ values.

1 data table match query

The elliptic flow,v_2, as a function of the transverse momentum,p_T, from 0–80% central Au+Au collisions for various particle species and energies.

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