Centrality dependence of the $p_{T}$ distribution for $K^{-}$ in Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. Errors are statistical only.

Centrality dependence of the $p_{T}$ distribution for protons in Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. Errors are statistical only.

Centrality dependence of the $p_{T}$ distribution for antiprotons in Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. Errors are statistical only.

Centrality dependence of the $p_{T}$ distribution for antiprotons in Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. Errors are statistical only.

Inverse slope parameters for $\pi^{+}$, $\pi^{-}$, $K^{+}$, $K^{-}$, proton, and antiproton for the 0-5%, 40-50%, and 60-92% centrality bins. Errors are statistical only.

Fit paramaters $T_{0}^{+}$ and $T_{0}^{-}$. Errors are statistical only.

Fit paramaters $u_{t}^{+}$ and $u_{t}^{-}$. Errors are statistical only.

Relationship between $N_{part}$ and centrality.

Mean transverse momentum as a function of centrality for pions, kaons, protons,and antiprotons in Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. Errors are systematic only.

dN/dy as a function of centrality for pions, kaons, protons,and antiprotons in Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. Errors are systematic only.

Particle ratios of $\pi^{-}$/$\pi^{+}$ for centrality 0-5% and 60-92%. Errors are statistical and systematic.

Particle ratios of $K^{-}$/$K^{+}$ for centrality 0-5% and 60-92%. Errors are statistical and systematic.

Particle ratios of antiprotons/protons for centrality 0-5%, 60-92%, and minimum bias. Errors are statistical and systematic.

Particle ratios of kaons/pions for centrality 0-5% and 60-92%. Errors are statistical and systematic.

Particle ratios of proton/$\pi^{+}$ and antiproton/$\pi^{-}$ for centrality 0-10%, 20-30%, and 60-92%. Errors are statistical and systematic.

Particle ratios of proton/$\pi^{0}$ and antiproton/$\pi^{0}$ for centrality 0-10%, 20-30%, and 60-92%. Errors are statistical and systematic.

Centrality dependence of particle ratios for $\pi^{-}$/$\pi^{+}$, $K^{-}$/$K^{+}$, and antiprotons/protons. Errors are statistical and systematic.

Rcp as a function of centrality 0-10% and 60-92% for ($\pi^{+}$ + $\pi^{-}$)/2. Errors are statistical only.

Rcp as a function of centrality 0-10% and 60-92% for ($K^{+}$ + $K^{-}$)/2. Errors are statistical only.

Rcp as a function of centrality 0-10% and 60-92% for charged (p+pbar)/2. Errors are statistical only.

Rcp as a function of centrality 0-10% and 60-92% for neutral pions. Errors are statistical only.

Integrated Rcp above $p_{T}$ = 1.5 GeV/c as a function of centrality 60-92% for pions, kaons, and (p+pbar)/2. Errors are statistical only.

Pion-kaon correlation functions and ratios of correlation functions. Errors are statistical only.

Pion-kaon correlation functions and ratios of correlation functions. Errors are statistical only.

Modeled pion-kaon correlation functions and ratios of correlation functions. Errors are statistical only from the calculations.

Modeled pion-kaon correlation functions and ratios of correlation functions. Errors are statistical only from the calculations.

$m_T$ spectra of $\Omega^-+\bar{\Omega}^+$ for 0-10% centrality. Errors listed here are the quadrature sum of statistical and point-to-point systematic uncertainties. There is an additional overall $m_T$-independent systematic uncertainty of 10%.

Fit parameters for $m_T$ spectra of $\Xi^-$.

Fit parameters for $m_T$ spectra of $\bar{\Xi}^+$.

Fit parameters for $m_T$ spectra of $\Omega^-+\bar{\Omega}^+$.

Particle ratio in 0-10% centrality.

Particle ratio in 0-10% centrality from the statiscal model.

Particle ratio from nonequilibrium model.

Particle ratio from HIJING/$B\bar{B}$.

Kinetic freeze-out temperature and transverse flow velocity obtained from the fits to $m_T$ spectra for 0-10% centrality.

Kinetic freeze-out temperature and transverse flow velocity of $\Xi^-+\bar{\Xi}^+$ (1$\sigma$ contour).

Kinetic freeze-out temperature and transverse flow velocity of $\Xi^-+\bar{\Xi}^+$ (2$\sigma$ contour).

Kinetic freeze-out temperature and transverse flow velocity of $\Xi^-+\bar{\Xi}^+$ (3$\sigma$ contour).

Kinetic freeze-out temperature and transverse flow velocity of $\pi$, $K$, $p$, $\Lambda$ (1$\sigma$ contour).

Kinetic freeze-out temperature and transverse flow velocity of $\pi$, $K$, $p$, $\Lambda$ (2$\sigma$ contour).

Kinetic freeze-out temperature and transverse flow velocity of $\pi$, $K$, $p$, $\Lambda$ (3$\sigma$ contour).

Mean transverse momentum $\langle p_T \rangle$. Results from best fits to spectra, Bose-Einstein for $\pi$, exponential for $K$, hydrodynamically-inspired function for $p$, and Boltzmann for $\Lambda$, $\Xi$, and $\Omega$.

Inclusive jet cross section DSIG/DETARAP for jets in the lab. frame. Data from the 1995-1997 data sample.

Inclusive jet cross section DSIG/DETARAP for jets in the lab. frame. Data from the 1999-2000 data sample.

Inclusive jet cross section DSIG/DETARAP for jets in the lab. frame. Data from the combined data sample.

Inclusive jet cross section DSIG/DET for jets in the lab. frame. Data from the 1995-1997 running period.

Inclusive jet cross section DSIG/DET for jets in the lab. frame. Data from the 1999-2000 running period.

Inclusive jet cross section DSIG/DET for jets in the lab. frame. Data from the combined running period.

Inclusive di-jet cross section DSIG/DQ**2 for jets in the lab. frame. Data from the 1995-1997 data sample.

Inclusive di-jet cross section DSIG/DQ**2 for jets in the lab. frame. Data from the 1999-2000 data sample.

Inclusive di-jet cross section DSIG/DQ**2 for jets in the lab. frame. Data from the combined data sample.

Inclusive di-jet cross section DSIG/DM for jets in the lab. frame. Data from the 1995-1997 sample.

Inclusive di-jet cross section DSIG/DM for jets in the lab. frame. Data from the 1999-2000 sample.

Inclusive di-jet cross section DSIG/DM for jets in the lab. frame. Data from the combined sample.

Mean subjet multiplicity as a function of the YCUT parameter used in defining the jet for the inclusive jet sample with ET 14 to 17 GeV and 17 to 21 GeV.

Mean subjet multiplicity as a function of the YCUT parameter used in defining the jet for the inclusive jet sample with ET 21 to 25 GeV and 25 to 35 GeV.

Mean subjet multiplicity as a function of the YCUT parameter used in defining the jet for the inclusive jet sample with ET 35 to 55 GeV and 55 to 119 GeV.

Measured values of the mean subjet multiplicity at YCUT = 0.01 as a function of Q**2.

Value of ALPHAS at the Z0 mass obtained from the data with ET(C=JET) > 25 GeV.. The second DSYS error is due to the uncertainty in the theory.

The v2 of KS0 as a function of pT for 30%–70%, 5%–30%, and 0%–5% of the collision cross section. The error bars represent statistical errors only. The nonflow systematic errors for the 30%–70%, 5%– 30%, and 0%–5% centralities are 25%, 20%, and 80%, respectively.

The v2 of Lambda+Lambdabar as a function of pT for 30%–70%, 5%–30%, and 0%–5% of the collision cross section. The error bars represent statistical errors only. The nonflow systematic errors for the 30%–70%, 5%– 30%, and 0%–5% centralities are 25%, 20%, and 80%, respectively.

The ratio RCP for KS0 at midrapidity calculated using centrality intervals, 0%–5% vs 40%–60% and 0%–5% vs 60%–80% of the collision cross section. The error bars shown on the points include both statistical and systematic errors.

The ratio RCP for Lambda+Lambdabar at midrapidity calculated using centrality intervals, 0%–5% vs 40%–60% and 0%–5% vs 60%–80% of the collision cross section. The error bars shown on the points include both statistical and systematic errors.

The v2 parameter for KS0 scaled by the number of constituent quarks (n) and plotted versus pT/n. The error bars shown include statistical and point-to-point systematic uncertainties from the background. The additional nonflow systematic uncertainties are approximately 20%.

The v2 parameter for Lambda+Lambdabar scaled by the number of constituent quarks (n) and plotted versus pT/n. The error bars shown include statistical and point-to-point systematic uncertainties from the background. The additional nonflow systematic uncertainties are approximately 20%.

Efficiency corrected two-particle azimuthal distributions for minimum bias and central d+Au collisions, and for p+p collisions. Curves are fits using Eq. 3, with parameters given in Table I. Trigger particles are selected with 4 GeV/c < $p_{T}$ (trig) < 6 GeV/c, while associated particles are selected within 2 GeV/c < $p_{T}$ < $p_{T}$ (trig), with |$\eta$| < 0.7 for both sets. Only statistical errors are listed. Normalization uncertainties are less than 5%.

Comparison of two-particle azimuthal distributions for central d+Au collisions to those seen in p+p and central Au+Au collisions. The respective pedestals have been subtracted. Trigger particles are selected with 4 GeV/c < $p_{T}$ (trig) < 6 GeV/c, while associated particles are selected within 2 GeV/c < $p_{T}$ < $p_{T}$ (trig), with |$\eta$| < 0.7 for both sets. Only statistical errors are listed. Normalization uncertainties are less than 5%.

Rapidity distribution of $\bar{p}$. Combined statitiscal uncertainty and systematic uncertainty from PID contramination. Systematic uncertainties from the track reconstruction efficiency are $\pm$25%.

Average transverse momentum of $p+\bar{p}$. Systematic uncertainties are $\pm$6%.

Average transverse momentum vs. centrality. Systematic error bands in figure are $\pm$6% for <pT>.

$dN/dy$ vs. centrality. Systematic error bands in figure are $\pm$25% for dN/dy.

$dN/dy$ vs. centrality. Systematic error bands in figure are $\pm$25% for dN/dy.

Average transverse momentum vs. the number of negative hadrons. Systematic error bands in figure are $\pm$6% for <pT>.

$dN/dy$ vs. the number of negative hadrons. Systematic error bands in figure are $\pm$25% for dN/dy.

$dN/dy$ vs. the number of negative hadrons. Systematic error bands in figure are $\pm$25% for dN/dy.

Measured cross section for kaon production as a function of W.

Differential cross section as a function of the ratio of the virtualities of the two photons.

Differential cross section as a function of the acolinearity angle PHI between the scattered electrons.

Differential cross section as a function of the acolinearity angle DEL(PHI) between the scattered electrons.

Differential cross section as a function of W of the hadronic system.

Differential cross section as a function of the Bjorken X.

Differential cross section as a function of the DIS Y variable.

Differential cross section as a function of LOG(S/S0).