Transverse momentum spectra for charged pions at midrapidity.

Transverse momentum spectra for protons at midrapidity.

Transverse momentum spectra for antiprotons at midrapidity.

Transverse momentum spectra for kaons at midrapidity.

dN/dy of pi+ and proton, normalised by N_part/2.

dN/dy of pi+ and proton, normalised by N_part/2.

dN/dy of pi+ and proton, normalised by N_part/2.

dN/dy of K+ and K-, normalised by N_part/2.

dN/dy of K+ and K-, normalised by N_part/2.

dN/dy of K+ and K-, normalised by N_part/2.

Transverse momentum of pi+, K+ and proton.

Transverse momentum of pi+, K+ and proton.

Transverse momentum of pi+, K+ and proton.

K-/K+, K-/pi-, p/pi+ and K+/pi+ vs. N_part.

K-/K+, K-/pi-, p/pi+ and K+/pi+ vs. N_part.

K-/K+, K-/pi-, p/pi+ and K+/pi+ vs. N_part.

dN/d_eta, normalised by N_part/2, as a function of sqrt(S_NN).

dN/dy, normalised by N_part/2; and m_t - m of pi+ and pi- as functions of sqrt(S_NN).

dN/dy, normalised by N_part/2; and m_t - m of K+ and K- as functions of sqrt(S_NN).

pi-/pi+, pbar/p, K-/K+, K+/pi+ and K-/pi- as functions of sqrt(S_NN).

v1 as a function of eta and eta/y-beam from different experiments and methods.

v2 as a function of p_T for different particle species and experiments.

v2 as a function of s_NN from different experiments.

T-mu_B plot for heavy-ion collisions at different s_NN.

The $\pi^0$ invariant mass peak positions and widths as a function of $p_{T}$ in 0-80% Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The $\pi^0$ invariant mass peak positions and widths as a function of $p_{T}$ in 0-80% Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The $\pi^0$ invariant mass peak positions and widths as a function of $p_{T}$ in 0-80% Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The $\pi^0$ invariant mass peak positions and widths as a function of $p_{T}$ in 0-80% Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The $\pi^0$ invariant mass peak positions and widths as a function of $p_{T}$ in 0-80% Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The $\pi^0$ invariant mass peak positions and widths as a function of $p_{T}$ in 0-80% Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

Photon conversion point radius distribution from real data and MC simulation in Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

Conversion probability correction factor for $\pi^0$ as a function of $p_{T}$

The overall detection efficiency of $\pi^0$ from embedding studt in 0-80% Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The overall detection efficiency of $\pi^0$ from embedding studt in 0-80% Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The overall detection efficiency of $\pi^0$ from embedding studt in 0-80% Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

Invariant yield of STAR $\pi^0$ as a function of $p_{T}$ at midrapidity for different collision centrality bins in Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

Invariant yield of STAR $\pi^0$ as a function of $p_{T}$ at midrapidity for different collision centrality bins in Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

Invariant yield of STAR $\pi^0$ as a function of $p_{T}$ at midrapidity for different collision centrality bins in Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The ratios of STAR $\pi^0$ spectra over $\pi^{\pm}$ from STAR and $\pi^0$ from PHENIX for different collision centrality bins in Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The nuclear modification factor $R_{CP}$ as a functon of $p_{T}$ of STAR $\pi^0$ in Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The nuclear modification factor $R_{AA}$ as a functon of $p_{T}$ of STAR $\pi^0$ in Au+Au collisions at $\sqrt{s_{NN}}=200$ GeV.

The differential cross section as a function of angle for W = 0.89 GeV.

The differential cross section as a function of angle for W = 0.91 GeV.

The differential cross section as a function of angle for W = 0.93 GeV.

The differential cross section as a function of angle for W = 0.95 GeV.

The differential cross section as a function of angle for W = 0.97 GeV.

The differential cross section as a function of angle for W = 0.99 GeV.

The differential cross section as a function of angle for W = 1.01 GeV.

The differential cross section as a function of angle for W = 1.03 GeV.

The differential cross section as a function of angle for W = 1.05 GeV.

The differential cross section as a function of angle for W = 1.07 GeV.

The differential cross section as a function of angle for W = 1.09 GeV.

The differential cross section as a function of angle for W = 1.11 GeV.

The differential cross section as a function of angle for W = 1.13 GeV.

The differential cross section as a function of angle for W = 1.15 GeV.

The differential cross section as a function of angle for W = 1.17 GeV.

The differential cross section as a function of angle for W = 1.19 GeV.

The differential cross section as a function of angle for W = 1.21 GeV.

The differential cross section as a function of angle for W = 1.23 GeV.

The differential cross section as a function of angle for W = 1.25 GeV.

The differential cross section as a function of angle for W = 1.27 GeV.

The differential cross section as a function of angle for W = 1.29 GeV.

The differential cross section as a function of angle for W = 1.31 GeV.

The differential cross section as a function of angle for W = 1.33 GeV.

The differential cross section as a function of angle for W = 1.35 GeV.

The differential cross section as a function of angle for W = 1.37 GeV.

The differential cross section as a function of angle for W = 1.39 GeV.

The differential cross section as a function of angle for W = 1.41 GeV.

The differential cross section as a function of angle for W = 1.43 GeV.

The differential cross section as a function of angle for W = 1.45 GeV.

The differential cross section as a function of angle for W = 1.47 GeV.

The differential cross section as a function of angle for W = 1.49 GeV.

The differential cross section as a function of angle for W = 1.51 GeV.

The differential cross section as a function of angle for W = 1.53 GeV.

The differential cross section as a function of angle for W = 1.55 GeV.

The differential cross section as a function of angle for W = 1.57 GeV.

The differential cross section as a function of angle for W = 1.59 GeV.

The differential cross section as a function of angle for W = 1.62 GeV.

The differential cross section as a function of angle for W = 1.66 GeV.

The differential cross section as a function of angle for W = 1.70 GeV.

The differential cross section as a function of angle for W = 1.74 GeV.

The differential cross section as a function of angle for W = 1.78 GeV.

The differential cross section as a function of angle for W = 1.82 GeV.

The differential cross section as a function of angle for W = 1.86 GeV.

The differential cross section as a function of angle for W = 1.90 GeV.

The differential cross section as a function of angle for W = 1.94 GeV.

The differential cross section as a function of angle for W = 1.98 GeV.

The differential cross section as a function of angle for W = 2.02 GeV.

The differential cross section as a function of angle for W = 2.06 GeV.

The differential cross section as a function of angle for W = 2.10 GeV.

The differential cross section as a function of angle for W = 2.14 GeV.

The differential cross section as a function of angle for W = 2.18 GeV.

The differential cross section as a function of angle for W = 2.22 GeV.

The differential cross section as a function of angle for W = 2.26 GeV.

The differential cross section as a function of angle for W = 2.30 GeV.

The differential cross section as a function of angle for W = 2.34 GeV.

The differential cross section as a function of angle for W = 2.38 GeV.

The differential cross section as a function of angle for W = 2.45 GeV.

The differential cross section as a function of angle for W = 2.55 GeV.

The differential cross section as a function of angle for W = 2.65 GeV.

The differential cross section as a function of angle for W = 2.75 GeV.

The differential cross section as a function of angle for W = 2.85 GeV.

The differential cross section as a function of angle for W = 2.95 GeV.

The differential cross section as a function of angle for W = 3.05 GeV.

The differential cross section as a function of angle for W = 3.15 GeV.

The differential cross section as a function of angle for W = 3.25 GeV.

The differential cross section as a function of angle for W = 3.35 GeV.

The differential cross section as a function of angle for W = 3.45 GeV.

The differential cross section as a function of angle for W = 3.55 GeV.

The differential cross section as a function of angle for W = 3.65 GeV.

The differential cross section as a function of angle for W = 3.75 GeV.

The differential cross section as a function of angle for W = 3.85 GeV.

The differential cross section as a function of angle for W = 3.95 GeV.

Normalized differential distribution in CHI(dijet) for two-jet mass 500 to 600 GeV and the non perturbative correction factor.

Normalized differential distribution in CHI(dijet) for two-jet mass 600 to 700 GeV and the non perturbative correction factor.

Normalized differential distribution in CHI(dijet) for two-jet mass 700 to 800 GeV and the non perturbative correction factor.

Normalized differential distribution in CHI(dijet) for two-jet mass 800 to 900 GeV and the non perturbative correction factor.

Normalized differential distribution in CHI(dijet) for two-jet mass 900 to 1000 GeV and the non perturbative correction factor.

Normalized differential distribution in CHI(dijet) for two-jet mass 1000 to1100 GeV and the non perturbative correction factor.

Normalized differential distribution in CHI(dijet) for two-jet mass > 1100 GeV and the non perturbative correction factor.

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Fig. 2. (Color online.) Event-by-event photon multiplicity distributions (solid circles) for $\mathrm{Au}+\mathrm{Au}$ and $\mathrm{Cu}+\mathrm{Cu}$ at $\sqrt{s_{\mathrm{NN}}}=62.4$ and $200 \mathrm{GeV} .$ The distributions for top $0-5 \%$ central $\mathrm{Au}+$ Au collisions and top $0-10 \%$ central $\mathrm{Cu}+\mathrm{Cu}$ collisions are also shown (open circles). The photon multiplicity distributions for central collisions are observed to be Gaussian (solid line). Only statistical errors are shown. NOTE: For points with invisible error bars, the point size was considered as an absolute upper limit for the uncertainty.

Fig. 2. (Color online.) Event-by-event photon multiplicity distributions (solid circles) for $\mathrm{Au}+\mathrm{Au}$ and $\mathrm{Cu}+\mathrm{Cu}$ at $\sqrt{s_{\mathrm{NN}}}=62.4$ and $200 \mathrm{GeV} .$ The distributions for top $0-5 \%$ central $\mathrm{Au}+$ Au collisions and top $0-10 \%$ central $\mathrm{Cu}+\mathrm{Cu}$ collisions are also shown (open circles). The photon multiplicity distributions for central collisions are observed to be Gaussian (solid line). Only statistical errors are shown. NOTE: For points with invisible error bars, the point size was considered as an absolute upper limit for the uncertainty.

Fig. 2. (Color online.) Event-by-event photon multiplicity distributions (solid circles) for $\mathrm{Au}+\mathrm{Au}$ and $\mathrm{Cu}+\mathrm{Cu}$ at $\sqrt{s_{\mathrm{NN}}}=62.4$ and $200 \mathrm{GeV} .$ The distributions for top $0-5 \%$ central $\mathrm{Au}+$ Au collisions and top $0-10 \%$ central $\mathrm{Cu}+\mathrm{Cu}$ collisions are also shown (open circles). The photon multiplicity distributions for central collisions are observed to be Gaussian (solid line). Only statistical errors are shown. NOTE: For points with invisible error bars, the point size was considered as an absolute upper limit for the uncertainty.

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

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

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

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

Fig. 4. (Color online.) Top panel: The number of photons divided by $\left\langle N_{\text{part}}\right\rangle / 2$ as a function of average number of participating nucleons for $\mathrm{Au}+\mathrm{Au}$ and $\mathrm{Cu}+\mathrm{Cu}$ at $\sqrt{\mathrm{s} _{\mathrm{NN}}}=62.4$ and $200 \mathrm{GeV}$ for $-3.7<\eta<-2.3 .$ Errors shown are systematic only and include those for $\left\langle N_{\text {part }}\right\rangle .$ Results from HIJING are shown as lines (solid for $\mathrm{Au}+\mathrm{Au}$ and dashed for $\mathrm{Cu}+\mathrm{Cu}$ ). Bottom panel: Same as above, for both photons and charged particles from PHOBOS [10]. NOTE: For points with invisible error bars, the point size was considered as an absolute upper limit for the uncertainty.

Fig. 4. (Color online.) Top panel: The number of photons divided by $\left\langle N_{\text{part}}\right\rangle / 2$ as a function of average number of participating nucleons for $\mathrm{Au}+\mathrm{Au}$ and $\mathrm{Cu}+\mathrm{Cu}$ at $\sqrt{\mathrm{s} _{\mathrm{NN}}}=62.4$ and $200 \mathrm{GeV}$ for $-3.7<\eta<-2.3 .$ Errors shown are systematic only and include those for $\left\langle N_{\text {part }}\right\rangle .$ Results from HIJING are shown as lines (solid for $\mathrm{Au}+\mathrm{Au}$ and dashed for $\mathrm{Cu}+\mathrm{Cu}$ ). Bottom panel: Same as above, for both photons and charged particles from PHOBOS [10]. NOTE: For points with invisible error bars, the point size was considered as an absolute upper limit for the uncertainty.

Fig. 5. (Color online.) Photon pseudorapidity distributions normalized by the average number of participating nucleon pairs for different collision centralities are plotted as a function of pseudorapidity shifted by the beam rapidity (-5.36 for $200 \mathrm{GeV}$ and -4.19 for $62.4 \mathrm{GeV}$ ) for $\mathrm{Au}+\mathrm{Au}$ and $\mathrm{Cu}+\mathrm{Cu}$ collisions at $\sqrt{s_{\mathrm{NN}}}=62.4$ and $200 \mathrm{GeV}$. Errors are systematic only, statistical errors are negligible in comparison. For clarity of presentation, results for only four centralities are shown. The $\mathrm{Cu}+$ Cu data are shifted by 0.1 unit in $\eta-y_{\text {beam }} .$ The solid line is a second order polynomial fit to the data (see text for details).

Fig. 5. (Color online.) Photon pseudorapidity distributions normalized by the average number of participating nucleon pairs for different collision centralities are plotted as a function of pseudorapidity shifted by the beam rapidity (-5.36 for $200 \mathrm{GeV}$ and -4.19 for $62.4 \mathrm{GeV}$ ) for $\mathrm{Au}+\mathrm{Au}$ and $\mathrm{Cu}+\mathrm{Cu}$ collisions at $\sqrt{s_{\mathrm{NN}}}=62.4$ and $200 \mathrm{GeV}$. Errors are systematic only, statistical errors are negligible in comparison. For clarity of presentation, results for only four centralities are shown. The $\mathrm{Cu}+$ Cu data are shifted by 0.1 unit in $\eta-y_{\text {beam }} .$ The solid line is a second order polynomial fit to the data (see text for details).

xT scaling (with xT.

J/psi nuclear modification factor RAA from sqrt(s).

J/psi nuclear modification factor RAA from sqrt(s).

J/psi-hadron azimuthal correlations in sqrt(s).

Contribution from B-hadron feed-down to inclusive J/psi production in sqrt(s).

Forward differential cross section for P P --> PI+ DEUT at beam momenta 1640 MeV.

Forward differential cross section for P P --> PI+ DEUT at beam momenta 1220 MeV.

Forward differential cross section for P P --> PI+ DEUT at beam momenta 995 MeV.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$N_{part}$ dependence of the near-side associated-particle yield.

$\Delta\phi$ distribution used to extract the away-side yield. The triangular pair acceptance correction in $\Delta\eta$ is not applied.

$N_{part}$ dependence of the away-side associated-particle yield.

$N_{part}$ dependence of the away-side associated-particle yield.

$N_{part}$ dependence of the away-side associated-particle yield.

$N_{part}$ dependence of the away-side associated-particle yield.

Away-side associated particle distribution.

$I_{AA}$.

$I_{AA}$.

$I_{AA}$.

$I_{AA}$.