Parameter $\alpha$ from the fit to the data.

Results of the measurements by PHENIX at $\sqrt{s_{NN}}$ = 200 GeV.

Results of the measurements by PHENIX at $\sqrt{s_{NN}}$ = 130 GeV.

Results of the measurements by PHENIX at $\sqrt{s_{NN}}$ = 19.6 GeV.

Ratios of measured quantities at 200 GeV/130 GeV and 200 GeV/19.6 GeV. The number of $N_P$ is the average between two energies.

Ratios of measured quantities at 200 GeV/130 GeV and 200 GeV/19.6 GeV. The number of $N_P$ is the average between two energies.

200, 130, and 19.6 GeV are RHIC average values, and 17.2, 8.7, and 4.8 GeV are SPS average values of $dN_{ch}$/$d\eta$/($0.5N_p$) at different $\sqrt{s_{NN}}$. An additional 5% error (recalc.) is added for collision energies 4.8 - 17.6 GeV for the uncertainty related to recalculation to the Center of Mass system.

200, 130, and 19.6 GeV are RHIC average values, and 17.2, 8.7, and 4.8 GeV are SPS average values of $dN_{ch}$/$d\eta$/($0.5N_p$) at different $\sqrt{s_{NN}}$. An additional 5% error (recalc.) is added for collision energies 4.8 - 17.6 GeV for the uncertainty related to recalculation to the Center of Mass system.

200, 130, and 19.6 GeV are RHIC average values, and 17.2, 8.7, and 4.8 GeV are SPS average values of $dN_{ch}$/$d\eta$/($0.5N_p$) at different $\sqrt{s_{NN}}$. An additional 5% error (recalc.) is added for collision energies 4.8 - 17.6 GeV for the uncertainty related to recalculation to the Center of Mass system.

200, 130, and 19.6 GeV are RHIC average values, and 17.2, 8.7, and 4.8 GeV are SPS average values of $dN_{ch}$/$d\eta$/($0.5N_p$) at different $\sqrt{s_{NN}}$. An additional 5% error (recalc.) is added for collision energies 4.8 - 17.6 GeV for the uncertainty related to recalculation to the Center of Mass system.

The longitudinal and transverse cross sections as a function of Q**2 for X Bjorken = 0.45.

The longitudinal and transverse cross sections as a function of Q**2 for X Bjorken = 0.52.

$\Delta\phi$ distributions for meson triggers with 2.5 < $p_T$ < 4.0 GeV/$c$ and associated charged hadrons with 1.7 < $p_T$ < 2.5 GeV/$c$ for 60-70% centrality in Au+Au collisions.

$\Delta\phi$ distributions for baryon triggers with 2.5 < $p_T$ < 4.0 GeV/$c$ and associated charged hadrons with 1.7 < $p_T$ < 2.5 GeV/$c$ for 60-70% centrality in Au+Au collisions.

Combinatorial Background Levels from Figure 1 Top Panels.

Combinatorial Background Levels from Figure 1 Bottom Panels.

Trigger Particle $v_2$ values.

Partner Particle $v_2$ values.

Yield per trigger for associated charged hadrons between 1.7 < $p_T$ < 2.5 GeV/$c$ for the near- (top) and away- (bottom) side jets.

Yield per trigger for associated charged hadrons between 1.7 < $p_T$ < 2.5 GeV/$c$ for the near- (top) and away- (bottom) side jets.

Uncertainties in Figure 2 as a function of $N_{part}$ and trigger type for AuAu and $d$+Au.

Uncertainties in Figure 2 as a function of $N_{part}$ and trigger type for AuAu and $d$+Au.

$p_T$ spectra of the near side associated charged hadrons corrected to the full jet yield for meson triggers at 2.5 < $p_T$ < 4.0 GeV/$c$ and $|\eta|$ < 0.35 for six centralities in Au+Au and $d$+Au collisions.

$p_T$ spectra of the near side associated charged hadrons corrected to the full jet yield for meson triggers at 2.5 < $p_T$ < 4.0 GeV/$c$ and $|\eta|$ < 0.35 for six centralities in Au+Au and $d$+Au collisions.

$p_T$ spectra of the near side associated charged hadrons corrected to the full jet yield for baryon triggers at 2.5 < $p_T$ < 4.0 GeV/$c$ and $|\eta|$ < 0.35 for six centralities in Au+Au, $d$+Au and $p$+$p$ collisions.

Inverse slopes from the fits in Figure 3.

Inverse slopes from the fits in Figure 3.

Inverse slopes from the fits in Figure 3.

$\bar{d}/d$ ratio vs. $p_T$ for minimum bias data.

Angular distributions of the photodisintegration cross section for angle between 130 and 160 degrees in the CM.

Bertsch-Pratt radius parameters versus the cube root of the number of participants ($N^{1/3}_{part}$) for $\pi^+\pi^+$ (blue squares) and $\pi^-\pi^-$ (red triangle) for the fits to a core-halo structure by Eq. (2) with statistical error bars and systematic error bands, in the 0.2 GeV/$c$ < $k_T$ < 2.0 GeV/$c$ range, with $<k_T>$ ~ 0.45 GeV/$c$. The solid line shows to $p_0$+$p_1$*$N^{1/3}_{part}$ for both signs.

Bertsch-Pratt radius parameters versus the cube root of the number of participants ($N^{1/3}_{part}$) for $\pi^+\pi^+$ (blue squares) and $\pi^-\pi^-$ (red triangle) for the fits to a core-halo structure by Eq. (2) with statistical error bars and systematic error bands, in the 0.2 GeV/$c$ < $k_T$ < 2.0 GeV/$c$ range, with $<k_T>$ ~ 0.45 GeV/$c$. The solid line shows to $p_0$+$p_1$*$N^{1/3}_{part}$ for both signs.

$F_{p_T}$ (in percent) of non-random fluctuations as a function of the $p_T$ range over which $M_{p_T}$ is calculated, 0.2 GeV/$c$ < $p_T$ < $p^{max}_T$, for the 20-25% centrality class ($N_{part}$ = 181.6).

The proton plus antiproton fraction and differential production rate per hadronic Z0 decay.

Differential production rates of charged pions per Z0 decay into light (u,d,s) and c and b quarks. The errors are combined statistical and systematic.

Differential production rates of charged kaons per Z0 decay into light (u,d,s) and c and b quarks. The errors are combined statistical and systematic.

Differential production rates of charged protons plus antiprotons per Z0 decay into light (u,d,s) and c and b quarks. The errors are combined statistical and systematic.

Differential production rates of stable charged particles per Z0 decay intolight (u,d,s) and c and b quarks. The errors are combined statistical and syste matic.

Differential production rate for positive and negative charged pions into light quark jets from hadronic Z0 decays. Also shown are the normalization differences. The ratios are defined as:-. R(Q=PI+)=(1/2N(Q=Z0))*D(N(QUARK --> PI+) + N(QUARKBAR --> PI-))/DX. R(Q=PI-)=(1/2N(Q=Z0))*D(N(QUARK --> PI-) + N(QUARKBAR --> PI+))/DX.

Differential production rate for positive and negative charged kaons into light quark jets from hadronic Z0 decays. Also shown are the normalization differences. The ratios are defined as:-. R(Q=K+)=(1/2N(Q=Z0))*D(N(QUARK --> K+) + N(QUARKBAR --> K-))/DX. R(Q=K-)=(1/2N(Q=Z0))*D(N(QUARK --> K-) + N(QUARKBAR --> K+))/DX.

Differential production rate for positive and negative protons into light quark jets from hadronic Z0 decays. Also shown are the normalization differences.The ratios are defined as:-. R(Q=P+)=(1/2N(Q=Z0))*D(N(QUARK --> P+) + N(QUARKBAR --> PBAR))/DX. R(Q=PBAR)=(1/2N(Q=Z0))*D(N(QUARK --> PBAR) + N(QUARKBAR --> P+))/DX.

$p_T$ spectra of charged hadrons for minimum bias collisions along with spectra for 9 centrality classes derived from the pseudo-rapidity region $|\eta|$ < 0.18. Stat. stands for statistical error, syst. stands for the systematic errors and occ. stands for occupancy error.

$p_T$ spectra of charged hadrons for minimum bias collisions along with spectra for 9 centrality classes derived from the pseudo-rapidity region $|\eta|$ < 0.18. Stat. stands for statistical error, syst. stands for the systematic errors and occ. stands for occupancy error.

Centrality dependence of $<p^{trunc}_T>$. Data points for truncated mean $p_T$ calculation for three $p_T$ ranges. The integral region is from 8 GeV/$c$ > $p_T$ > $p_{T_{min}}$ for the most peripheral bin. Since the data stop around 6.5 GeV/$c$, truncated mean $p_T$ is lower.

Ratio of charged hadron yields per nucleon-nucleon collision between central (0-10%) and peripheral (60-92%) Au + Au collisions. Stat. stands for statistical error, syst. stands for the systematic errors and occ. stands for occupancy error.

$R_{AA}$ for $(h^++h^-)/2$ and $\pi^0$ as function of $p_{T}$ for minimum bias and 9 centrality classes. Stat. stands for statistical error from Au+Au. The asymmetric uncertainty from the fit of the $\pi^0$ mass peak is denoted by fit. $\sigma_{ENBC}$ stands for error on number of binary collisions. Error from $pp$ parametrization that is not $p_T$ dependent. This error is not included in the calculation of the Upper bound of the systematic error and the Lower bound of the systematic error.

$R_{AA}$ for $(h^++h^-)/2$ and $\pi^0$ as function of $p_{T}$ for minimum bias and 9 centrality classes. Stat. stands for statistical error from Au+Au. The asymmetric uncertainty from the fit of the $\pi^0$ mass peak is denoted by fit. $\sigma_{ENBC}$ stands for error on number of binary collisions. Error from $pp$ parametrization that is not $p_T$ dependent. This error is not included in the calculation of the Upper bound of the systematic error and the Lower bound of the systematic error.

$R_{AA}$ for $(h^++h^-)/2$ and $\pi^0$ as function of $p_{T}$ for minimum bias and 9 centrality classes. Stat. stands for statistical error from Au+Au. The asymmetric uncertainty from the fit of the $\pi^0$ mass peak is denoted by fit. $\sigma_{ENBC}$ stands for error on number of binary collisions. Error from $pp$ parametrization that is not $p_T$ dependent. This error is not included in the calculation of the Upper bound of the systematic error and the Lower bound of the systematic error.

Charged hadron to $\pi^0$ ratios for minimum bias events and 9 centrality classes.

Charged hadron to $\pi^0$ ratios for minimum bias events and 9 centrality classes.

Charged hadron to $\pi^0$ ratios for minimum bias events and 9 centrality classes.

Charged hadron to $\pi^0$ ratios for minimum bias events and 9 centrality classes.

Charged hadron to $\pi^0$ ratios for minimum bias events and 9 centrality classes.

Charged hadron to $\pi^0$ ratios for minimum bias events and 9 centrality classes.

Au + Au yield integrated for $p_T$ > 4.5 (GeV/$c$) over the $N$ + $N$ yield, normalized using either $N_{coll}$ or $N_{part}$, plot as a function of $<N_{part}>$. Statistical and systematic error from Au+Au and $N$+$N$ reference includes: a) $NN$ reference error with 10.4% normalization error subtracted, this error is 11.2%, b) systematic error on Au+Au is 8.5% (correction), and c) 5% occupancy correction (it is centrality dependent). Error on $N_{coll}$+10.4% error on $N$+$N$ reference.

Au + Au yield integrated for $p_T$ > 4.5 (GeV/$c$) over the $N$ + $N$ yield, normalized using either $N_{coll}$ or $N_{part}$, plot as a function of $<N_{part}>$. Statistical and systematic error from Au+Au and $N$+$N$ reference includes: a) $NN$ reference error with 10.4% normalization error subtracted, this error is 11.2%, b) systematic error on Au+Au is 8.5% (correction), and c) 5% occupancy correction (it is centrality dependent). Error on $N_{coll}$+10.4% error on $N$+$N$ reference.

Invariant yields from the $p$+$p$ reference data. The normalization uncertainty is labeled norm, the uncertainty from the fit is labeled fit, and the uncertainty $\pi^0$ is from the $\pi^0$ ratio.