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A search for the pair production of heavy vector-like partners T and B of the top and bottom quarks has been performed by the CMS experiment at the CERN LHC using proton-proton collisions at $\sqrt{s} =$ 13 TeV. The data sample was collected in 2016 and corresponds to an integrated luminosity of 35.9 fb$^{-1}$. Final states studied for $\mathrm{T\overline{T}}$ production include those where one of the T quarks decays via T $\to$ tZ and the other via T $\to$ bW, tZ, or tH, where H is a Higgs boson. For the $\mathrm{B\overline{B}}$ case, final states include those where one of the B quarks decays via B $\to$ bZ and the other B $\to$ tW, bZ, or bH. Events with two oppositely charged electrons or muons, consistent with coming from the decay of a Z boson, and jets are investigated. The number of observed events is consistent with standard model background estimations. Lower limits at 95% confidence level are placed on the masses of the T and B quarks for a range of branching fractions. Assuming 100% branching fractions for T $\to$ tZ, and B $\to$ bZ, T and B quark mass values below 1280 and 1130 GeV, respectively, are excluded.
The $S_{\rm T}$ distribution for group A before fitting.
The $S_{\rm T}$ distribution for group A before fitting.
The $S_{\rm T}$ distribution for group B before fitting.
The $S_{\rm T}$ distribution for group B before fitting.
The $S_{\rm T}$ distribution for group C before fitting.
The $S_{\rm T}$ distribution for group C before fitting.
The $S_{\rm T}$ distribution for group D before fitting.
The $S_{\rm T}$ distribution for group D before fitting.
The observed and expected 95% CL upper limits on the $T\bar T$ cross section as a function of the T quark mass assuming Br(T → tZ) = 100%.
The observed and expected 95% CL upper limits on the $T\bar T$ cross section as a function of the T quark mass assuming Br(T → tZ) = 100%.
The observed and expected 95% CL upper limits on the $T\bar T$ cross section as a function of the T quark mass assuming Br(T → tZ) = B(T → tH) = 50%.
The observed and expected 95% CL upper limits on the $T\bar T$ cross section as a function of the T quark mass assuming Br(T → tZ) = B(T → tH) = 50%.
The observed and expected 95% CL upper limits on the $T\bar T$ cross section as a function of the T quark mass assuming Br(T → tZ) = B(T → bW) = 50%
The observed and expected 95% CL upper limits on the $T\bar T$ cross section as a function of the T quark mass assuming Br(T → tZ) = B(T → bW) = 50%
The number of observed events and the predicted number of SM background events in the $T\bar T$ search using electron channel in the four event groups.
The number of observed events and the predicted number of SM background events in the $T\bar T$ search using electron channel in the four event groups.
The number of observed events and the predicted number of SM background events in the $T\bar T$ search using muon channel in the four event groups.
The number of observed events and the predicted number of SM background events in the $T\bar T$ search using muon channel in the four event groups.
The $S_{\rm T}$ distribution for 1b event category for data and the expected background before fitting.
The $S_{\rm T}$ distribution for 1b event category for data and the expected background before fitting.
The $S_{\rm T}$ distribution for 2b event category for data and the expected background.
The $S_{\rm T}$ distribution for 2b event category for data and the expected background.
The $S_{\rm T}$ distribution for boosted t event category for data and the expected background.
The $S_{\rm T}$ distribution for boosted t event category for data and the expected background.
The $S_{\rm T}$ distribution for boosted H event category for data and the expected background.
The $S_{\rm T}$ distribution for boosted H event category for data and the expected background.
The $S_{\rm T}$ distribution for boosted Z event category for data and the expected background.
The $S_{\rm T}$ distribution for boosted Z event category for data and the expected background.
The observed and expected 95% CL upper limits on the $B\bar B$ cross section as a function of the B quark mass assuming Br(B → bZ) = 100%.
The observed and expected 95% CL upper limits on the $B\bar B$ cross section as a function of the B quark mass assuming Br(B → bZ) = 100%.
The observed and expected 95% CL upper limits on the $B\bar B$ cross section as a function of the B quark mass assuming Br(B → bZ) = Br(B → bH) = 50%.
The observed and expected 95% CL upper limits on the $B\bar B$ cross section as a function of the B quark mass assuming Br(B → bZ) = Br(B → bH) = 50%.
The observed and expected 95% CL upper limits on the $B\bar B$ cross section as a function of the B quark mass assuming Br(B → bZ) = Br(B → tW) = 50%
The observed and expected 95% CL upper limits on the $B\bar B$ cross section as a function of the B quark mass assuming Br(B → bZ) = Br(B → tW) = 50%
The number of observed events and the predicted number of SM background events in the $B\bar B$ search using electron channel in the five event categories.
The number of observed events and the predicted number of SM background events in the $B\bar B$ search using electron channel in the five event categories.
The number of observed events and the predicted number of SM background events in the $B\bar B$ search using muon channel in the five event categories.
The number of observed events and the predicted number of SM background events in the $B\bar B$ search using muon channel in the five event categories.
This paper presents measurements of $t\bar{t}$ production in association with additional $b$-jets in $pp$ collisions at the LHC at a centre-of-mass energy of 13 TeV. The data were recorded with the ATLAS detector and correspond to an integrated luminosity of 36.1 fb$^{-1}$. Fiducial cross-section measurements are performed in the dilepton and lepton-plus-jets $t\bar{t}$ decay channels. Results are presented at particle level in the form of inclusive cross-sections of $t\bar{t}$ final states with three and four $b$-jets as well as differential cross-sections as a function of global event properties and properties of $b$-jet pairs. The measured inclusive fiducial cross-sections generally exceed the $t\bar{t}b\bar{b}$ predictions from various next-to-leading-order matrix element calculations matched to a parton shower but are compatible within the total uncertainties. The experimental uncertainties are smaller than the uncertainties in the predictions. Comparisons of state-of-the-art theoretical predictions with the differential measurements are shown and good agreement with data is found for most of them.
The measured fiducial cross sections
The measured fiducial cross sections
Relative differential cross section as a function of the b-jet multiplicity in emu channel
Relative differential cross section as a function of the b-jet multiplicity in emu channel
Relative differential cross section as a function of H_T in emu channel
Relative differential cross section as a function of H_T in emu channel
Relative differential cross section as a function of H_Thad in emu channel
Relative differential cross section as a function of H_Thad in emu channel
Relative differential cross section as a function of H_T in leptons+jets channel
Relative differential cross section as a function of H_T in leptons+jets channel
Relative differential cross section as a function of H_Thad in leptons+jets channel
Relative differential cross section as a function of H_Thad in leptons+jets channel
Relative differential cross section as a function of pT of leading b-jet in emu channel
Relative differential cross section as a function of pT of leading b-jet in emu channel
Relative differential cross section as a function of pT of sub-leading b-jet in emu channel
Relative differential cross section as a function of pT of sub-leading b-jet in emu channel
Relative differential cross section as a function of pT of third-leading b-jet in emu channel
Relative differential cross section as a function of pT of third-leading b-jet in emu channel
Relative differential cross section as a function of pT of leading b-jet in lepton+jets channel
Relative differential cross section as a function of pT of leading b-jet in lepton+jets channel
Relative differential cross section as a function of pT of sub-leading b-jet in lepton+jets channel
Relative differential cross section as a function of pT of sub-leading b-jet in lepton+jets channel
Relative differential cross section as a function of pT of third-leading b-jet in lepton+jets channel
Relative differential cross section as a function of pT of third-leading b-jet in lepton+jets channel
Relative differential cross section as a function of pT of fourth-leading b-jet in lepton+jets channel
Relative differential cross section as a function of pT of fourth-leading b-jet in lepton+jets channel
Relative differential cross section as a function of invarant mass of two highest pT b-jets in emu channel
Relative differential cross section as a function of invarant mass of two highest pT b-jets in emu channel
Relative differential cross section as a function of pT of two highest pT b-jets in emu channel
Relative differential cross section as a function of pT of two highest pT b-jets in emu channel
Relative differential cross section as a function of deltaR of two highest pT b-jets in emu channel
Relative differential cross section as a function of deltaR of two highest pT b-jets in emu channel
Relative differential cross section as a function of invariant mass of two highest pT b-jets in lepton+jets channel
Relative differential cross section as a function of invariant mass of two highest pT b-jets in lepton+jets channel
Relative differential cross section as a function of pT of two highest pT b-jets in lepton+jets channel
Relative differential cross section as a function of pT of two highest pT b-jets in lepton+jets channel
Relative differential cross section as a function of deltaR of two highest pT b-jets in lepton+jets channel
Relative differential cross section as a function of deltaR of two highest pT b-jets in lepton+jets channel
Relative differential cross section as a function of invariant mass of two closest b-jets in deltaR in emu channel
Relative differential cross section as a function of invariant mass of two closest b-jets in deltaR in emu channel
Relative differential cross section as a function of pT of two closest b-jets in deltaR in emu channel
Relative differential cross section as a function of pT of two closest b-jets in deltaR in emu channel
Relative differential cross section as a function of deltaR of two closest b-jets in deltaR in emu channel
Relative differential cross section as a function of deltaR of two closest b-jets in deltaR in emu channel
Relative differential cross section as a function of invariant mass of two closest b-jets in deltaR in lepton+jets channel
Relative differential cross section as a function of invariant mass of two closest b-jets in deltaR in lepton+jets channel
Relative differential cross section as a function of pT of two closest b-jets in deltaR in lepton+jets channel
Relative differential cross section as a function of pT of two closest b-jets in deltaR in lepton+jets channel
Relative differential cross section as a function of deltaR of two closest b-jets in deltaR in lepton+jets channel
Relative differential cross section as a function of deltaR of two closest b-jets in deltaR in lepton+jets channel
A search for magnetic monopoles and high-electric-charge objects is presented using 34.4 fb$^{-1}$ of 13 TeV $pp$ collision data collected by the ATLAS detector at the LHC during 2015 and 2016. The considered signature is based upon high ionization in the transition radiation tracker of the inner detector associated with a pencil-shape energy deposit in the electromagnetic calorimeter. The data were collected by a dedicated trigger based on the tracker high-threshold hit capability. The results are interpreted in models of Drell-Yan pair production of stable particles with two spin hypotheses (0 and 1/2) and masses ranging from 200 GeV to 4000 GeV. The search improves by approximately a factor of five the constraints on the direct production of magnetic monopoles carrying one or two Dirac magnetic charges and stable objects with electric charge in the range $20\le|z|\le60$ and extends the charge range to $60<|z|\le100$.
Observed 95% confidence-level upper limits on the cross section for Drell-Yan spin-0 monopole production as a function of mass for magnetic charges $|g|=1g_D$ and $|g|=2g_D$.
Observed 95% confidence-level upper limits on the cross section for Drell-Yan spin-0 HECO production as a function of mass for various values of electric charge in the range $20\le|z|\le100$.
Observed 95% confidence-level upper limits on the cross section for Drell-Yan spin-1/2 monopole production as a function of mass for magnetic charges $|g|=1g_D$ and $|g|=2g_D$.
Observed 95% confidence-level upper limits on the cross section for Drell-Yan spin-1/2 HECO production as a function of mass for various values of electric charge in the range $20\le|z|\le100$.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=1g_\textrm{D}$ monopoles of mass 200 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=1g_\textrm{D}$ monopoles of mass 500 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=1g_\textrm{D}$ monopoles of mass 1000 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=1g_\textrm{D}$ monopoles of mass 1500 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=1g_\textrm{D}$ monopoles of mass 2000 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=1g_\textrm{D}$ monopoles of mass 2500 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=1g_\textrm{D}$ monopoles of mass 3000 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=1g_\textrm{D}$ monopoles of mass 4000 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=2g_\textrm{D}$ monopoles of mass 200 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=2g_\textrm{D}$ monopoles of mass 500 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=2g_\textrm{D}$ monopoles of mass 1000 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=2g_\textrm{D}$ monopoles of mass 1500 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=2g_\textrm{D}$ monopoles of mass 2000 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=2g_\textrm{D}$ monopoles of mass 2500 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=2g_\textrm{D}$ monopoles of mass 3000 GeV.
Selection efficiency as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for $g=2g_\textrm{D}$ monopoles of mass 4000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=20$ of mass 200 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=20$ of mass 500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=20$ of mass 1000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=20$ of mass 1500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=20$ of mass 2000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=20$ of mass 2500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=20$ of mass 3000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=20$ of mass 4000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=40$ of mass 200 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=40$ of mass 500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=40$ of mass 1000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=40$ of mass 1500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=40$ of mass 2000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=40$ of mass 2500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=40$ of mass 3000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=40$ of mass 4000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=60$ of mass 200 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=60$ of mass 500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=60$ of mass 1000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=60$ of mass 1500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=60$ of mass 2000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=60$ of mass 2500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=60$ of mass 3000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=60$ of mass 4000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=80$ of mass 200 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=80$ of mass 500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=80$ of mass 1000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=80$ of mass 1500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=80$ of mass 2000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=80$ of mass 2500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=80$ of mass 3000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=80$ of mass 4000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=100$ of mass 200 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=100$ of mass 500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=100$ of mass 1000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=100$ of mass 1500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=100$ of mass 2000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=100$ of mass 2500 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=100$ of mass 3000 GeV.
Total selection efficiency (i.e., the fraction of MC HECOs surviving the trigger and offline selection criteria) as a function of transverse kinetic energy $E^\text{kin}_\text{T}=E_\text{kin}\sin\theta$ and pseudorapidity $|\eta|$ for HECOs of charge $|z|=100$ of mass 4000 GeV.
A measurement of the coupling strength of the Higgs boson to a pair of tau leptons is performed using events recorded in proton-proton collisions by the CMS experiment at the LHC in 2016 at a center-of-mass energy of 13 TeV. The data set corresponds to an integrated luminosity of 35.9 inverse femtobarns. The H to tau tau signal is established with a significance of 4.9 standard deviations, to be compared to an expected significance of 4.7 standard deviations. The best fit of the product of the observed H to tau tau signal production cross section and branching fraction is 1.09 +0.27-0.26 times the standard model expectation. The combination with the corresponding measurement performed with data collected by the CMS experiment at center-of-mass energies of 7 and 8 TeV leads to an observed significance of 5.9 standard deviations, equal to the expected significance. This is the first observation of Higgs boson decays to tau leptons by a single experiment.
Local p-value and significance as a function of the SM Higgs boson mass hypothesis. The observation (red, solid) is compared to the expectation (blue, dashed) for a Higgs boson with a mass mH = 125.09 GeV. The background includes Higgs boson decays to pairs of W bosons, with mH = 125.09 GeV.
Local p-value and significance as a function of the SM Higgs boson mass hypothesis. The observation (red, solid) is compared to the expectation (blue, dashed) for a Higgs boson with a mass mH = 125.09 GeV. The background includes Higgs boson decays to pairs of W bosons, with mH = 125.09 GeV.
Best fit signal strength per category (left) and channel (right), for mH = 125.09 GeV. The constraints from the global fit are used to extract each of the individual best fit signal strengths. The combined best fit signal strength is μ = 1.09+0.27
Best fit signal strength per category, for mH = 125.09 GeV. The constraints from the global fit are used to extract each of the individual best fit signal strengths. The combined best fit signal strength is μ = 1.09+0.27
Best fit signal strength per channel, for mH = 125.09 GeV. The constraints from the global fit are used to extract each of the individual best fit signal strengths. The combined best fit signal strength is μ = 1.09+0.27
Measurements of differential top quark pair $\mathrm{t\overline{t}}$ cross sections using events produced in proton-proton collisions at a centre-of-mass energy of 13 TeV containing two oppositely charged leptons are presented. The data were recorded by the CMS experiment at the CERN LHC in 2016 and correspond to an integrated luminosity of 35.9 fb$^{-1}$. The differential cross sections are presented as functions of kinematic observables of the top quarks and their decay products, the $\mathrm{t\overline{t}}$ system, and the total number of jets in the event. The differential cross sections are defined both with particle-level objects in a fiducial phase space close to that of the detector acceptance and with parton-level top quarks in the full phase space. All results are compared with standard model predictions from Monte Carlo simulations with next-to-leading-order (NLO) accuracy in quantum chromodynamics (QCD) at matrix-element level interfaced to parton-shower simulations. Where possible, parton-level results are compared to calculations with beyond-NLO precision in QCD. Significant disagreement is observed between data and all predictions for several observables. The measurements are used to constrain the top quark chromomagnetic dipole moment in an effective field theory framework at NLO in QCD and to extract $\mathrm{t\overline{t}}$ and leptonic charge asymmetries.
Measured absolute differential cross section at parton level as a function of $p_{T}^{t}$.
Covariance matrix of the absolute differential cross section at parton level as a function of $p_{T}^{t}$.
Measured normalised differential cross section at parton level as a function of $p_{T}^{t}$.
Covariance matrix of the normalised differential cross section at parton level as a function of $p_{T}^{t}$.
Measured absolute differential cross section at particle level as a function of $p_{T}^{t}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{t}$.
Measured normalised differential cross section at particle level as a function of $p_{T}^{t}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{t}$.
Measured absolute differential cross section at parton level as a function of $p_{T}^{\bar{t}}$.
Covariance matrix of the absolute differential cross section at parton level as a function of $p_{T}^{\bar{t}}$.
Measured normalised differential cross section at parton level as a function of $p_{T}^{\bar{t}}$.
Covariance matrix of the normalised differential cross section at parton level as a function of $p_{T}^{\bar{t}}$.
Measured absolute differential cross section at particle level as a function of $p_{T}^{\bar{t}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{\bar{t}}$.
Measured normalised differential cross section at particle level as a function of $p_{T}^{\bar{t}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{\bar{t}}$.
Measured absolute differential cross section at parton level as a function of $p_{T}^{t}$ (leading).
Covariance matrix of the absolute differential cross section at parton level as a function of $p_{T}^{t}$ (leading).
Measured normalised differential cross section at parton level as a function of $p_{T}^{t}$ (leading).
Covariance matrix of the normalised differential cross section at parton level as a function of $p_{T}^{t}$ (leading).
Measured absolute differential cross section at particle level as a function of $p_{T}^{t}$ (leading).
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{t}$ (leading).
Measured normalised differential cross section at particle level as a function of $p_{T}^{t}$ (leading).
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{t}$ (leading).
Measured absolute differential cross section at parton level as a function of $p_{T}^{t}$ (trailing).
Covariance matrix of the absolute differential cross section at parton level as a function of $p_{T}^{t}$ (trailing).
Measured normalised differential cross section at parton level as a function of $p_{T}^{t}$ (trailing).
Covariance matrix of the normalised differential cross section at parton level as a function of $p_{T}^{t}$ (trailing).
Measured absolute differential cross section at particle level as a function of $p_{T}^{t}$ (trailing).
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{t}$ (trailing).
Measured normalised differential cross section at particle level as a function of $p_{T}^{t}$ (trailing).
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{t}$ (trailing).
Measured absolute differential cross section at parton level as a function of $p_{T}^{t}$($t\bar{t}$ RF).
Covariance matrix of the absolute differential cross section at parton level as a function of $p_{T}^{t}$($t\bar{t}$ RF).
Measured normalised differential cross section at parton level as a function of $p_{T}^{t}$($t\bar{t}$ RF).
Covariance matrix of the normalised differential cross section at parton level as a function of $p_{T}^{t}$($t\bar{t}$ RF).
Measured absolute differential cross section at particle level as a function of $p_{T}^{t}$($t\bar{t}$ RF).
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{t}$($t\bar{t}$ RF).
Measured normalised differential cross section at particle level as a function of $p_{T}^{t}$($t\bar{t}$ RF).
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{t}$($t\bar{t}$ RF).
Measured absolute differential cross section at parton level as a function of $y_{t}$.
Covariance matrix of the absolute differential cross section at parton level as a function of $y_{t}$.
Measured normalised differential cross section at parton level as a function of $y_{t}$.
Covariance matrix of the normalised differential cross section at parton level as a function of $y_{t}$.
Measured absolute differential cross section at particle level as a function of $y_{t}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $y_{t}$.
Measured normalised differential cross section at particle level as a function of $y_{t}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $y_{t}$.
Measured absolute differential cross section at parton level as a function of $y_{\bar{t}}$.
Covariance matrix of the absolute differential cross section at parton level as a function of $y_{\bar{t}}$.
Measured normalised differential cross section at parton level as a function of $y_{\bar{t}}$.
Covariance matrix of the normalised differential cross section at parton level as a function of $y_{\bar{t}}$.
Measured absolute differential cross section at particle level as a function of $y_{\bar{t}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $y_{\bar{t}}$.
Measured normalised differential cross section at particle level as a function of $y_{\bar{t}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $y_{\bar{t}}$.
Measured absolute differential cross section at parton level as a function of $y_{t}$ (leading).
Covariance matrix of the absolute differential cross section at parton level as a function of $y_{t}$ (leading).
Measured normalised differential cross section at parton level as a function of $y_{t}$ (leading).
Covariance matrix of the normalised differential cross section at parton level as a function of $y_{t}$ (leading).
Measured absolute differential cross section at particle level as a function of $y_{t}$ (leading).
Covariance matrix of the absolute differential cross section at particle level as a function of $y_{t}$ (leading).
Measured normalised differential cross section at particle level as a function of $y_{t}$ (leading).
Covariance matrix of the normalised differential cross section at particle level as a function of $y_{t}$ (leading).
Measured absolute differential cross section at parton level as a function of $y_{t}$ (trailing).
Covariance matrix of the absolute differential cross section at parton level as a function of $y_{t}$ (trailing).
Measured normalised differential cross section at parton level as a function of $y_{t}$ (trailing).
Covariance matrix of the normalised differential cross section at parton level as a function of $y_{t}$ (trailing).
Measured absolute differential cross section at particle level as a function of $y_{t}$ (trailing).
Covariance matrix of the absolute differential cross section at particle level as a function of $y_{t}$ (trailing).
Measured normalised differential cross section at particle level as a function of $y_{t}$ (trailing).
Covariance matrix of the normalised differential cross section at particle level as a function of $y_{t}$ (trailing).
Measured absolute differential cross section at parton level as a function of $p_{T}^{t\bar{t}}$.
Covariance matrix of the absolute differential cross section at parton level as a function of $p_{T}^{t\bar{t}}$.
Measured normalised differential cross section at parton level as a function of $p_{T}^{t\bar{t}}$.
Covariance matrix of the normalised differential cross section at parton level as a function of $p_{T}^{t\bar{t}}$.
Measured absolute differential cross section at particle level as a function of $p_{T}^{t\bar{t}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{t\bar{t}}$.
Measured normalised differential cross section at particle level as a function of $p_{T}^{t\bar{t}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{t\bar{t}}$.
Measured absolute differential cross section at parton level as a function of $y_{t\bar{t}}$.
Covariance matrix of the absolute differential cross section at parton level as a function of $y_{t\bar{t}}$.
Measured normalised differential cross section at parton level as a function of $y_{t\bar{t}}$.
Covariance matrix of the normalised differential cross section at parton level as a function of $y_{t\bar{t}}$.
Measured absolute differential cross section at particle level as a function of $y_{t\bar{t}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $y_{t\bar{t}}$.
Measured normalised differential cross section at particle level as a function of $y_{t\bar{t}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $y_{t\bar{t}}$.
Measured absolute differential cross section at parton level as a function of $m_{t\bar{t}}$.
Covariance matrix of the absolute differential cross section at parton level as a function of $m_{t\bar{t}}$.
Measured normalised differential cross section at parton level as a function of $m_{t\bar{t}}$.
Covariance matrix of the normalised differential cross section at parton level as a function of $m_{t\bar{t}}$.
Measured absolute differential cross section at particle level as a function of $m_{t\bar{t}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $m_{t\bar{t}}$.
Measured normalised differential cross section at particle level as a function of $m_{t\bar{t}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $m_{t\bar{t}}$.
Measured absolute differential cross section at parton level as a function of $\Delta|y|(t,\bar{t})$.
Covariance matrix of the absolute differential cross section at parton level as a function of $\Delta|y|(t,\bar{t})$.
Measured normalised differential cross section at parton level as a function of $\Delta|y|(t,\bar{t})$.
Covariance matrix of the normalised differential cross section at parton level as a function of $\Delta|y|(t,\bar{t})$.
Measured absolute differential cross section at particle level as a function of $\Delta|y|(t,\bar{t})$.
Covariance matrix of the absolute differential cross section at particle level as a function of $\Delta|y|(t,\bar{t})$.
Measured normalised differential cross section at particle level as a function of $\Delta|y|(t,\bar{t})$.
Covariance matrix of the normalised differential cross section at particle level as a function of $\Delta|y|(t,\bar{t})$.
Measured absolute differential cross section at parton level as a function of $\Delta\phi(t,\bar{t})$.
Covariance matrix of the absolute differential cross section at parton level as a function of $\Delta\phi(t,\bar{t})$.
Measured normalised differential cross section at parton level as a function of $\Delta\phi(t,\bar{t})$.
Covariance matrix of the normalised differential cross section at parton level as a function of $\Delta\phi(t,\bar{t})$.
Measured absolute differential cross section at particle level as a function of $\Delta\phi(t,\bar{t})$.
Covariance matrix of the absolute differential cross section at particle level as a function of $\Delta\phi(t,\bar{t})$.
Measured normalised differential cross section at particle level as a function of $\Delta\phi(t,\bar{t})$.
Covariance matrix of the normalised differential cross section at particle level as a function of $\Delta\phi(t,\bar{t})$.
Measured absolute differential cross section at particle level as a function of $p_{T}^{l}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{l}$.
Measured normalised differential cross section at particle level as a function of $p_{T}^{l}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{l}$.
Measured absolute differential cross section at particle level as a function of $p_{T}^{\bar{l}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{\bar{l}}$.
Measured normalised differential cross section at particle level as a function of $p_{T}^{\bar{l}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{\bar{l}}$.
Measured absolute differential cross section at particle level as a function of $p_{T}^{l}$ (leading).
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{l}$ (leading).
Measured normalised differential cross section at particle level as a function of $p_{T}^{l}$ (leading).
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{l}$ (leading).
Measured absolute differential cross section at particle level as a function of $p_{T}^{l}$ (trailing).
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{l}$ (trailing).
Measured normalised differential cross section at particle level as a function of $p_{T}^{l}$ (trailing).
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{l}$ (trailing).
Measured absolute differential cross section at particle level as a function of $\eta_{l}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $\eta_{l}$.
Measured normalised differential cross section at particle level as a function of $\eta_{l}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $\eta_{l}$.
Measured absolute differential cross section at particle level as a function of $\eta_{\bar{l}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $\eta_{\bar{l}}$.
Measured normalised differential cross section at particle level as a function of $\eta_{\bar{l}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $\eta_{\bar{l}}$.
Measured absolute differential cross section at particle level as a function of $\eta_{l}$ (leading).
Covariance matrix of the absolute differential cross section at particle level as a function of $\eta_{l}$ (leading).
Measured normalised differential cross section at particle level as a function of $\eta_{l}$ (leading).
Covariance matrix of the normalised differential cross section at particle level as a function of $\eta_{l}$ (leading).
Measured absolute differential cross section at particle level as a function of $\eta_{l}$ (trailing).
Covariance matrix of the absolute differential cross section at particle level as a function of $\eta_{l}$ (trailing).
Measured normalised differential cross section at particle level as a function of $\eta_{l}$ (trailing).
Covariance matrix of the normalised differential cross section at particle level as a function of $\eta_{l}$ (trailing).
Measured absolute differential cross section at particle level as a function of $p_{T}^{l\bar{l}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{l\bar{l}}$.
Measured normalised differential cross section at particle level as a function of $p_{T}^{l\bar{l}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{l\bar{l}}$.
Measured absolute differential cross section at particle level as a function of $m_{l\bar{l}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $m_{l\bar{l}}$.
Measured normalised differential cross section at particle level as a function of $m_{l\bar{l}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $m_{l\bar{l}}$.
Measured absolute differential cross section at particle level as a function of $\Delta\phi(l,\bar{l})$.
Covariance matrix of the absolute differential cross section at particle level as a function of $\Delta\phi(l,\bar{l})$.
Measured normalised differential cross section at particle level as a function of $\Delta\phi(l,\bar{l})$.
Covariance matrix of the normalised differential cross section at particle level as a function of $\Delta\phi(l,\bar{l})$.
Measured absolute differential cross section at particle level as a function of $\Delta|\eta|(l,\bar{l})$.
Covariance matrix of the absolute differential cross section at particle level as a function of $\Delta|\eta|(l,\bar{l})$.
Measured normalised differential cross section at particle level as a function of $\Delta|\eta|(l,\bar{l})$.
Covariance matrix of the normalised differential cross section at particle level as a function of $\Delta|\eta|(l,\bar{l})$.
Measured absolute differential cross section at particle level as a function of $p_{T}^{b}$ (leading).
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{b}$ (leading).
Measured normalised differential cross section at particle level as a function of $p_{T}^{b}$ (leading).
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{b}$ (leading).
Measured absolute differential cross section at particle level as a function of $p_{T}^{b}$ (trailing).
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{b}$ (trailing).
Measured normalised differential cross section at particle level as a function of $p_{T}^{b}$ (trailing).
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{b}$ (trailing).
Measured absolute differential cross section at particle level as a function of $\eta_{b}$ (leading).
Covariance matrix of the absolute differential cross section at particle level as a function of $\eta_{b}$ (leading).
Measured normalised differential cross section at particle level as a function of $\eta_{b}$ (leading).
Covariance matrix of the normalised differential cross section at particle level as a function of $\eta_{b}$ (leading).
Measured absolute differential cross section at particle level as a function of $\eta_{b}$ (trailing).
Covariance matrix of the absolute differential cross section at particle level as a function of $\eta_{b}$ (trailing).
Measured normalised differential cross section at particle level as a function of $\eta_{b}$ (trailing).
Covariance matrix of the normalised differential cross section at particle level as a function of $\eta_{b}$ (trailing).
Measured absolute differential cross section at particle level as a function of $p_{T}^{b\bar{b}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $p_{T}^{b\bar{b}}$.
Measured normalised differential cross section at particle level as a function of $p_{T}^{b\bar{b}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $p_{T}^{b\bar{b}}$.
Measured absolute differential cross section at particle level as a function of $m_{b\bar{b}}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $m_{b\bar{b}}$.
Measured normalised differential cross section at particle level as a function of $m_{b\bar{b}}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $m_{b\bar{b}}$.
Measured absolute differential cross section at particle level as a function of $N_{jets}$.
Covariance matrix of the absolute differential cross section at particle level as a function of $N_{jets}$.
Measured normalised differential cross section at particle level as a function of $N_{jets}$.
Covariance matrix of the normalised differential cross section at particle level as a function of $N_{jets}$.
The WZ production cross section is measured in proton-proton collisions at a centre-of-mass energy $\sqrt{s} =$ 13 TeV using data collected with the CMS detector, corresponding to an integrated luminosity of 35.9 fb$^{-1}$. The inclusive cross section is measured to be $\sigma_{\text{tot}}$(pp $\to$ WZ$)$ = 48.09 $^{+1.00}_{-0.96}$ (stat) $^{+0.44}_{-0.37}$ (theo) $^{+2.39}_{-2.17}$ (syst) $\pm$ 1.39 (lumi) pb, resulting in a total uncertainty of $-$2.78/$+$2.98 pb. Fiducial cross section and ratios of charge-dependent cross section measurements are provided. Differential cross section measurements are also presented with respect to three variables: the Z boson transverse momentum $p_\mathrm{T}$, the leading jet $p_\mathrm{T}$, and the $m$(WZ) variable, defined as the invariant mass of the system composed of the three leptons and the missing transverse momentum. Differential measurements with respect to the W boson $p_\mathrm{T}$, separated by charge, are also shown. Results are consistent with standard model predictions, favouring next-to-next-to-leading-order predictions over those at next-to-leading order. Constraints on anomalous triple gauge couplings are derived via a binned maximum likelihood fit to the $m$(WZ) variable.
Differential cross section in bins of pT(Z). Values are expressed as a fraction of the total cross section. The eee and eem final states are shown.
Expected and observed one-dimensional confidence intervals (CI) at 95% confidence level for each of the considered EFT parameters, accounting only for the interference term between the SM amplitude and the BSM one. The one-dimensional intervals for each parameter are computed fixing the other two parameters to zero, the SM value.
Expected and observed one-dimensional confidence intervals (CI) at 95% confidence level for each of the considered EFT parameters. Both the square matrix of the dimension-6 contribution and the interference term between the SM amplitude and the BSM one are accounted for. The one-dimensional intervals for each parameter are computed fixing the other two parametes to zero, the SM value.
Differential cross section in bins of pT(Z). Values are expressed as a fraction of the total cross section. The inclusive final state is shown.
Differential cross section in bins of pT(Z). Values are expressed as a fraction of the total cross section. The emm and mmm final states are shown.
Differential cross section in bins of mass of the WZ system. Values are expressed as a fraction of the total cross section.
Measured WZ production cross sections computed separately in each of the flavour categories.
Measured fiducial cross sections and their corresponding uncertainties for each of the individual flavour categories, as well as for the combination of the four. The combined value is the result of a symultaneous fit to the four categories, therefore both the central value and its total uncertaintydiffer from the sum of the central values and the quadratic sum of the uncertainties respectively, because of correlations among sources of uncertainty in the categorized values.
Differential cross section in bins of pT(leading jet). Values are expressed as a fraction of the total cross section. The inclusive final state is shown.
Expected and observed yields for each of the relevant processes and flavour categories. Combined statistical and systematic uncertainties are shown for each case except for the observed data yields for which only statistical uncertainties are presented. All expected yields correspond to quantities estimated after the maximum likelihood fit. Uncertainties are computed taking into account the full correlation matrix between sources of uncertainty, processes, and flavour categories.
Differential cross section in bins of pT(leading jet). Values are expressed as a fraction of the total cross section. The eee, eem, emm, and mmm final states are shown.
Summary of the total postfit impact of each uncertainty source on the uncertainty in the signal strength measurement, for the four flavour categories and their combination. Theoretical uncertainties are only included in the signal acceptance during the extrapolation to the total phase space, so they are not included in the likelihood fit. The values are percentages and correspond to half the difference between the up and down variation of each systematic uncertainty component.
Efficiencies estimated as transfer factors from the fiducial region to the signal region using generator-level information, for an integrated luminosity L of 35.9 inverse femtobarn. Statistical, scale, and PDF uncertainties are later propagated to the final cross section measurement.
Measured WZ production cross section computed in the inclusive final state and split by W boson charge, and asymmetry ratio.
This paper presents measurements of the $W^+ \rightarrow \mu^+\nu$ and $W^- \rightarrow \mu^-\nu$ cross-sections and the associated charge asymmetry as a function of the absolute pseudorapidity of the decay muon. The data were collected in proton--proton collisions at a centre-of-mass energy of 8 TeV with the ATLAS experiment at the LHC and correspond to a total integrated luminosity of $20.2~\mbox{fb$^{-1}$}$. The precision of the cross-section measurements varies between 0.8% to 1.5% as a function of the pseudorapidity, excluding the 1.9% uncertainty on the integrated luminosity. The charge asymmetry is measured with an uncertainty between 0.002 and 0.003. The results are compared with predictions based on next-to-next-to-leading-order calculations with various parton distribution functions and have the sensitivity to discriminate between them.
The correction factors, $C_{W^±,i}$ with their associated systematic uncertainties as a function of $|\eta_{\mu}|$, for $W^+$ and $W^−$
The integrated global correction factor $C_{W^±}$, for $W^+$ and $W^−$
Cross-sections (differential in $\eta_{\mu}$) and asymmetry, as a function of $|\eta_{\mu}|$). The central values are provided along with the statistical and dominant systematic uncertainties: the data statistical uncertainty (Data Stat.), the $E_T^{\textrm{miss}}$ uncertainty, the uncertainties related to muon reconstruction (Muon Reco.), those related to the background, those from MC statistics (MC Stat.), and modelling uncertainties. The uncertainties of the cross-sections are given in percent and those of the asymmetry as an absolute difference from the nominal.
The measured fiducial production cross-sections times branching ratio for $W^+\rightarrow\mu^+\nu$ and $W^-\rightarrow\mu^-\bar{\nu}$, their sum, and their ratio for data
The measured fiducial production cross-sections times branching ratio for $W^+\rightarrow\mu^+ u$ and $W^-\rightarrow\mu^-\bar{\nu}$, their sum, and their ratio for the predictions from DYNNLO (CT14 NNLO PDF set)
Size of the $W^{+}$ the cross-section (differential in $\eta_{\mu}$, as a function of $|\eta_{\mu}|$. The central values are provided along with the statistical and systematic uncertainties together with the sign information. gThe uncertainties are given in percent.
Size of the $W^{+}$ the cross-section (differential in $\eta_{\mu}$, as a function of $|\eta_{\mu}|$. The central values are provided along with the statistical and systematic uncertainties together with the sign information. gThe uncertainties are given in percent.
Size of the asymmetry as a function of $|\eta_{\mu}|$. The central values are provided along with the statistical and systematic uncertainties together with the sign information. The uncertainties are given as an absolute difference from the nominal.
A test of CP invariance in Higgs boson production via vector-boson fusion is performed in the $H\rightarrow\tau\tau$ decay channel. This test uses the Optimal Observable method and is carried out using 36.1 $\mathrm{fb}^{-1}$ of $\sqrt{s}$ = 13 TeV proton$-$proton collision data collected by the ATLAS experiment at the LHC. Contributions from CP-violating interactions between the Higgs boson and electroweak gauge bosons are described by an effective field theory, in which the parameter $\tilde{d}$ governs the strength of CP violation. No sign of CP violation is observed in the distributions of the Optimal Observable, and $\tilde{d}$ is constrained to the interval $[-0.090, 0.035]$ at the 68% confidence level (CL), compared to an expected interval of $\tilde{d} \in [-0.035,0.033]$ based upon the Standard Model prediction. No constraints can be set on $\tilde{d}$ at 95% CL, while an expected 95% CL interval of $\tilde{d} \in [-0.21,0.15]$ for the Standard Model hypothesis was expected.
Post-fit BDT distributions after the VBF event selection for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ SF analysis channel. The VBF signal is shown for $\mu = 0.73$ and $\tilde d = -0.01$. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leptons depends on the trigger.
Post-fit BDT distributions after the VBF event selection for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ DF analysis channel. The VBF signal is shown for $\mu = 0.73$ and $\tilde d = -0.01$. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given.
Post-fit BDT distributions after the VBF event selection for the $\tau_{\mathrm{lep}}\tau_{\mathrm{had}}$ analysis channel. The VBF signal is shown for $\mu = 0.73$ and $\tilde d = -0.01$. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leading lepton depends on the trigger.
Post-fit BDT distributions after the VBF event selection for the $\tau_{\mathrm{had}}\tau_{\mathrm{had}}$ analysis channel. The VBF signal is shown for $\mu = 0.73$ and $\tilde d = -0.01$. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given.
Post-fit $m_{\tau\tau}^{\mathrm{MMC}}$ distributions in the low BDT score CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ SF analysis channel. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leptons depends on the trigger.
Post-fit $m_{\tau\tau}^{\mathrm{MMC}}$ distributions in the low BDT score CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ DF analysis channel. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given.
Post-fit $m_{\tau\tau}^{\mathrm{MMC}}$ distributions in the low BDT score CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{had}}$ analysis channel. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leading lepton depends on the trigger.
Post-fit $m_{\tau\tau}^{\mathrm{MMC}}$ distributions in the low BDT score CR for the $\tau_{\mathrm{had}}\tau_{\mathrm{had}}$ analysis channel. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given.
Post-fit Optimal Observable distributions in the low BDT score CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ SF analysis channel. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leptons depends on the trigger.
Post-fit Optimal Observable distributions in the low BDT score CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ DF analysis channel. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given.
Post-fit Optimal Observable distributions in the low BDT score CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{had}}$ analysis channel. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leading lepton depends on the trigger.
Post-fit Optimal Observable distributions in the low BDT score CR for the $\tau_{\mathrm{had}}\tau_{\mathrm{had}}$ analysis channel. ''Other bkg'' denotes all background contributions not listed explicitly in the legend. The size of the combined statistical, experimental, and theoretical uncertainties is given.
Post-fit distributions of the event yields as a function of the Optimal Observable in the SR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ SF analysis channel. The values of $\tilde d$, the signal strength $\mu$, the normalization of background processes, and nuisance parameters for the event yield prediction are set to those which minimize the NLL. The size of the combined statistical, experimental and theoretical uncertainties is given.
Post-fit distributions of the event yields as a function of the Optimal Observable in the SR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ DF analysis channel. The values of $\tilde d$, the signal strength $\mu$, the normalization of background processes, and nuisance parameters for the event yield prediction are set to those which minimize the NLL. The size of the combined statistical, experimental and theoretical uncertainties is given.
Post-fit distributions of the event yields as a function of the Optimal Observable in the SR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{had}}$ analysis channel. The values of $\tilde d$, the signal strength $\mu$, the normalization of background processes, and nuisance parameters for the event yield prediction are set to those which minimize the NLL. The size of the combined statistical, experimental and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leading lepton depends on the trigger.
Post-fit distributions of the event yields as a function of the Optimal Observable in the SR for the $\tau_{\mathrm{had}}\tau_{\mathrm{had}}$ analysis channel. The values of $\tilde d$, the signal strength $\mu$, the normalization of background processes, and nuisance parameters for the event yield prediction are set to those which minimize the NLL. The size of the combined statistical, experimental and theoretical uncertainties is given.
The observed $\Delta\mathrm{NLL}$ curve as a function of $\tilde d$ values. For comparison, expected $\Delta\mathrm{NLL}$ curves are also shown. The constraints on the nuisance parameters and normalization factors are first determined in a CR-only fit, and then a fit to pseudo-data corresponding to these nuisance parameters, normalization factors, and to $\tilde d=0, \mu = 1$ or $\tilde d =0, \mu = 0.73$ is performed to obtain these $\Delta\mathrm{NLL}$ curves. Moreover, a pre-fit expected $\Delta\mathrm{NLL}$ is shown, using pseudo-data corresponding to $\tilde d =0$ and $\mu = 1$ in the signal and control regions.
The expected $\Delta\mathrm{NLL}$ curves comparing the sensitivity of the fit with and without systematic uncertainties. For comparison, other curves are shown which remove the effect of jet-based systematic uncertainties, $\tau$-based systematic uncertainties, and MC statistical uncertainties.
The observed $\Delta\mathrm{NLL}$ curves for each analysis channel as a function of $\tilde d$, compared to the combined result. For the individual analysis channel $\Delta\mathrm{NLL}$ curves, only event yield information in the other SRs is used, ensuring that the Optimal Observable distributions in the other SRs do not influence the preferred value of $\tilde d$. The signal strength is constrained to be positive in these individual channel $\Delta\mathrm{NLL}$ curves. The exact value of the $p_{\mathrm{T}}$ cut on the leading lepton depends on the trigger.
Post-fit BDT distributions in the top-quark CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ SF channel. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leptons depends on the trigger.
Post-fit BDT distributions in the top-quark CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ DF channel. The size of the combined statistical, experimental, and theoretical uncertainties is given.
Post-fit BDT distributions in the $Z\to \ell\ell$ CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ SF analysis channel. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leptons depends on the trigger.
Post-fit Optimal Observable distributions in the top-quark CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ SF channel. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leptons depends on the trigger.
Post-fit Optimal Observable distributions in the top-quark CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ DF channel. The size of the combined statistical, experimental, and theoretical uncertainties is given.
Post-fit Optimal Observable distributions in the $Z\to \ell\ell$ CR for the $\tau_{\mathrm{lep}}\tau_{\mathrm{lep}}$ SF analysis channel. The size of the combined statistical, experimental, and theoretical uncertainties is given. The exact value of the $p_{\mathrm{T}}$ cut on the leptons depends on the trigger.
Post-fit distribution of weighted event yields as a function of the Optimal Observable for all four SRs combined. The contributions of the different SRs are weighted by a factor of ln(1 + S/B), where S and B are the post-fit expected numbers of signal and background events in that region, respectively. The size of the combined statistical, experimental, and theoretical uncertainties is given.
This paper presents measurements of charged-particle distributions sensitive to the properties of the underlying event in events containing a $Z$ boson decaying into a muon pair. The data were obtained using the ATLAS detector at the LHC in proton-proton collisions at a centre-of-mass energy of 13 TeV with an integrated luminosity of 3.2 fb$^{-1}$. Distributions of the charged-particle multiplicity and of the charged-particle transverse momentum are measured in regions of the azimuth defined relative to the $Z$ boson direction. The measured distributions are compared with the predictions of various Monte Carlo generators which implement different underlying-event models. The Monte Carlo model predictions qualitatively describe the data well, but with some significant discrepancies.
Figure 09d, mean sumPt toward, toward region : Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
transverse region : Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
Figure 09c, mean sumPt transmin, transmin region : Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
transmax region : Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
away region : Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
Figure 09b, mean nTracks toward, toward region: Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
transverse region: Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
Figure 09a, mean nTracks transmin, transmin region: Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
transmax region: Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
away region: Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
Figure 10b, mean meanPt toward, toward region : Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
transverse region : Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
Figure 10a, mean meanPt transmin, transmin region : Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
transmax region : Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
away region : Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
Figure 04c from auxiliary figures, mean sumPt toward low thrust, toward region : low thrust ($T<0.75$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
transverse region : low thrust ($T<0.75$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
Figure 11c, mean sumPt transmin low thrust, transmin region : low thrust ($T<0.75$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
transmax region : low thrust ($T<0.75$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
away region : low thrust ($T<0.75$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
Figure 04a from auxiliary figures, mean nTracks toward low thrust, toward region : low thrust ($T<0.75$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
transverse region : low thrust ($T<0.75$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
Figure 11a, mean nTracks transmin low thrust, transmin region : low thrust ($T<0.75$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
transmax region : low thrust ($T<0.75$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
away region : low thrust ($T<0.75$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
Figure 06a from auxiliary figures, mean meanPt toward low thrust, toward region : low thrust ($T<0.75$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
transverse region : low thrust ($T<0.75$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
Figure 12a, mean meanPt transmin low thrust, transmin region : low thrust ($T<0.75$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
transmax region : low thrust ($T<0.75$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
away region : low thrust ($T<0.75$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
Figure 04d from auxiliary figures, mean sumPt toward high thrust, toward region : hight thrust ($0.75\leq T$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
transverse region : hight thrust ($0.75\leq T$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
Figure 11d, mean sumPt transmin high thrust, transmin region : hight thrust ($0.75\leq T$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
transmax region : hight thrust ($0.75\leq T$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
away region : hight thrust ($0.75\leq T$) Mean sum of transverse momenta ($\langle \Sigma p_{T} \rangle \pm stat. \pm syst.det. \pm syst.gen.[GeV]$)
Figure 04b from auxiliary figures, mean nTracks toward high thrust, toward region : hight thrust ($0.75\leq T$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
transverse region : hight thrust ($0.75\leq T$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
Figure 11b, mean nTracks transmin high thrust, transmin region : hight thrust ($0.75\leq T$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
transmax region : hight thrust ($0.75\leq T$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
away region : hight thrust ($0.75\leq T$) Mean charged particle multiplicity ($\langle N_{ch} \rangle \pm stat. \pm syst.det. \pm syst.gen.$)
Figure 06b from auxiliary figures, mean meanPt toward high thrust, toward region : hight thrust ($0.75\leq T$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
transverse region : hight thrust ($0.75\leq T$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
Figure 12b, mean meanPt transmin high thrust, transmin region : hight thrust ($0.75\leq T$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
transmax region : hight thrust ($0.75\leq T$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
away region : hight thrust ($0.75\leq T$) Mean of arithmetic mean of transverse momenta ($\langle mean p_{T} \rangle \pm stat. \pm syst.det.\pm syst.gen.[GeV]$)
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$0GeV<p_{T}^{Z}<10GeV$
Figure 01a from auxiliary figures, ptSpec toward_zptregion2, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$80GeV<p_{T}^{Z}<120GeV$
Figure 02a from auxiliary figures, ptSpec toward_zptregion7, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$0GeV<p_{T}^{Z}<10GeV$
Figure 04a, ptSpec transmin_zptregion2, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$80GeV<p_{T}^{Z}<120GeV$
Figure 05a, ptSpec transmin_zptregion7, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,toward region,$0GeV<p_{T}^{Z}<10GeV$
Figure 01b from auxiliary figures, nTracks toward_zptregion2, $\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,toward region,$80GeV<p_{T}^{Z}<120GeV$
Figure 02b from auxiliary figures, nTracks toward_zptregion7, $\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmin region,$0GeV<p_{T}^{Z}<10GeV$
Figure 04b, nTracks transmin_zptregion2, $\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmin region,$80GeV<p_{T}^{Z}<120GeV$
Figure 05b, nTracks transmin_zptregion7, $\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$0GeV<p_{T}^{Z}<10GeV$
Figure 01c from auxiliary figures, sumPt toward_zptregion2, $\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$80GeV<p_{T}^{Z}<120GeV$
Figure 02c from auxiliary figures, sumPt toward_zptregion7, $\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$0GeV<p_{T}^{Z}<10GeV$
Figure 04c, sumPt transmin_zptregion2, $\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$80GeV<p_{T}^{Z}<120GeV$
Figure 05c, sumPt transmin_zptregion7, $\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$0GeV<p_{T}^{Z}<10GeV$
Figure 01d from auxiliary figures, meanPt toward_zptregion2, $\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$80GeV<p_{T}^{Z}<120GeV$
Figure 02d from auxiliary figures, meanPt toward_zptregion7, $\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$0GeV<p_{T}^{Z}<10GeV$
Figure 04d, meanPt transmin_zptregion2, $\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$80GeV<p_{T}^{Z}<120GeV$
Figure 05d, meanPt transmin_zptregion7, $\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$0GeV<p_{T}^{Z}<10GeV$
Figure 03a from auxiliary figures, ptSpec toward_zptregion2 low thrust, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$80GeV<p_{T}^{Z}<120GeV$
Figure 03c from auxiliary figures, ptSpec toward_zptregion7 low thrust, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$0GeV<p_{T}^{Z}<10GeV$
Figure 06a, ptSpec transmin_zptregion2 low thrust, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$80GeV<p_{T}^{Z}<120GeV$
Figure 06c, ptSpec transmin_zptregion7 low thrust, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{t}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),toward region,$0GeV<p_{T}^{Z}<10GeV$
Figure 05a from auxiliary figures, nTracks toward_zptregion2 low thrust, $\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),toward region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmin region,$0GeV<p_{T}^{Z}<10GeV$
Figure 07a, nTracks transmin_zptregion2 low thrust, $\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmin region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,low thrust(T<0.75),away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,low thrust(T<0.75),away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),toward region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),toward region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmin region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmin region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{N_{ev}}{d(mean p_{t})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust(T<0.75),away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$0GeV<p_{T}^{Z}<10GeV$
Figure 03b from auxiliary figures, ptSpec toward_zptregion2 high thrust, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$80GeV<p_{T}^{Z}<120GeV$
Figure 03d from auxiliary figures, ptSpec toward_zptregion7 high thrust, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$0GeV<p_{T}^{Z}<10GeV$
Figure 06b, ptSpec transmin_zptregion2 high thrust, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$80GeV<p_{T}^{Z}<120GeV$
Figure 06d, ptSpec transmin_zptregion7 high thrust, $\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ch}} \frac{dN_{ch}}{dp_{T}}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),toward region,$0GeV<p_{T}^{Z}<10GeV$
Figure 05b from auxiliary figures, nTracks toward_zptregion2 high thrust, $\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),toward region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmin region,$0GeV<p_{T}^{Z}<10GeV$
Figure 07b, nTracks transmin_zptregion2 high thrust, $\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmin region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{dN_{ch}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.$,high thrust (0.75<=T$),away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d\Sigma p_{t}/\delta\eta\delta\phi}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75=<T),away region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),toward region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),toward region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),toward region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),toward region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),toward region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),toward region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),toward region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),toward region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transverse region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transverse region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transverse region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transverse region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transverse region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transverse region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transverse region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transverse region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmin region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmin region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmin region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmin region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmin region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmin region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmin region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmin region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmax region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmax region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmax region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmax region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmax region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmax region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmax region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),transmax region,$200GeV<p_{T}^{Z}<500GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),away region,$0GeV<p_{T}^{Z}<10GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),away region,$10GeV<p_{T}^{Z}<20GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),away region,$20GeV<p_{T}^{Z}<40GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),away region,$40GeV<p_{T}^{Z}<60GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),away region,$60GeV<p_{T}^{Z}<80GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),away region,$80GeV<p_{T}^{Z}<120GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),away region,$120GeV<p_{T}^{Z}<200GeV$
$\frac{1}{N_{ev}} \frac{dN_{ev}}{d(mean p_{T})}\pm stat.\pm syst.gen.\pm syst.det.[GeV^{-1}]$,high thrust (0.75<=T),away region,$200GeV<p_{T}^{Z}<500GeV$
The average total energy as well as its hadronic and electromagnetic components are measured with the CMS detector at pseudorapidities $-$6.6 $<\eta<-$5.2 in proton-proton collisions at a centre-of-mass energy $\sqrt{s}=$ 13 TeV. The results are presented as a function of the charged particle multiplicity in the region $|\eta|< $2. This measurement is sensitive to correlations induced by the underlying event structure over a very wide pseudorapidity region. The predictions of Monte Carlo event generators commonly used in collider experiments and ultra-high energy cosmic ray physics are compared to the data.
Average total energy reconstructed in the region −6.6 < eta < −5.2 as a function of the number of reconstructed tracks for abs(eta)<2.
Average total energiy reconstructed in the region −6.6 < eta < −5.2 normalised to that in the first bin (Nch< 10) as a function of the number of reconstructed tracks for abs(eta)<2.
Average electromagnetic energy reconstructed in the region −6.6 < eta < −5.2 as a function of the number of reconstructed tracks for abs(eta)<2.
Average hadronic energy reconstructed in the region −6.6 < eta < −5.2 as a function of the number of reconstructed tracks for abs(eta)<2.
Ratio of the average electromagnetic and hadronic energies reconstructed in the region −6.6 < eta < −5.2 as a function of the number of reconstructed tracks for abs(eta)<2.
When you search on a word, e.g. 'collisions', we will automatically search across everything we store about a record. But, sometimes you may wish to be more specific. Here we show you how.
Guidance and examples on the query string syntax can be found in the Elasticsearch documentation.
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