Fit results based on $k(\delta_{\eta})$=$1/{{2\alpha\xi}/{\delta_{\eta}}}$ ($\xi << \delta_{\eta}$).

$m^2$ (signal+background) distribution for $\bar{d}$,$d$ for $p_T$ = 1.6-2.9 GeV/$c$.

$m^2$ (background) distribution for $\bar{d}$,$d$ for $p_T$ = 1.6-2.9 GeV/$c$.

$m^2$ (signal) distribution for $\bar{d}$,$d$ for $p_T$ = 1.6-2.9 GeV/$c$.

Comparison of differential $v_2(p_T)$ for $\pi^{\pm}$. Results are shown for 20-60% central Au+Au collisions.

Comparison of differential $v_2(p_T)$ for $K^{\pm}$. Results are shown for 20-60% central Au+Au collisions.

Comparison of differential $v_2(p_T)$ for $(\bar{p})p$. Results are shown for 20-60% central Au+Au collisions.

Comparison of differential $v_2(p_T)$ for $\phi$ mesons. Results are shown for 20-60% central Au+Au collisions.

Comparison of differential $v_2(p_T)$ for $(\bar{d})d$. Results are shown for 20-60% central Au+Au collisions.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

$v_2$ vs $KE_T$ for several identified particle species obtained in mid-central Au+Au collisions, and ${v_2}/{n_q}$ vs ${KE_T}/{n_q}$ for the same particle species.

V0 V0 cross section for PI- on C target.

V0 V0 cross section for SIGMA- on CU target.

V0 V0 cross section for SIGMA- on C target.

Feynman X distributions of the first LAMBDA in LAMBDA LAMBDA production from SIGMA- on C and CU targets.

Feynman X distributions of the second LAMBDA in LAMBDA LAMBDA production from SIGMA- on C and CU targets.

Feynman X distributions of the first LAMBDA in LAMBDA LAMBDA production from PI- on C and CU targets.

Feynman X distributions of the second LAMBDA in LAMBDA LAMBDA production from PI- on C and CU targets.

Feynman X distributions of the first LAMBDA in LAMBDA LAMBDA production from N on C and CU targets.

Feynman X distributions of the second LAMBDA in LAMBDA LAMBDA production from N on C and CU targets.

Feynman X distributions of the LAMBDA in LAMBDA K0S production from SIGMA- on C and CU targets.

Feynman X distributions of the K0S in LAMBDA K0S production from SIGMA- on C and CU targets.

Feynman X distributions of the LAMBDA in LAMBDA K0S production from PI- on C and CU targets.

Feynman X distributions of the K0S in LAMBDA K0S production from PI- on C and CU targets.

Feynman X distributions of the LAMBDA in LAMBDA K0S production from N on C and CU targets.

Feynman X distributions of the K0S in LAMBDA K0S production from N on C and CU targets.

Feynman X distributions of the LAMBDA in LAMBDA LAMBDABAR production from SIGMA- on C and CU targets.

Feynman X distributions of the LAMBDABAR in LAMBDA LAMBDABAR production from SIGMA- on C and CU targets.

Feynman X distributions of the LAMBDA in LAMBDA LAMBDABAR production from PI- on C and CU targets.

Feynman X distributions of the LAMBDABAR in LAMBDA LAMBDABAR production from PI- on C and CU targets.

Feynman X distributions of the LAMBDA in LAMBDA LAMBDABAR production from N on C and CU targets.

Feynman X distributions of the LAMBDABAR in LAMBDA LAMBDABAR production from N on C and CU targets.

Feynman X distributions of the first K0s in K0S K0S production from SIGMA- on C and CU targets.

Feynman X distributions of the second K0s in K0S K0S production from SIGMA- on C and CU targets.

Feynman X distributions of the first K0s in K0S K0S production from PI- on C and CU targets.

Feynman X distributions of the second K0s in K0S K0S production from PI- on C and CU targets.

Feynman X distributions of the first K0s in K0S K0S production from N on C and CU targets.

Feynman X distributions of the second K0s in K0S K0S production from N on C and CU targets.

Feynman X distributions of the LAMBDABAR in LAMBDABAR K0S production from SIGMA- on C and CU targets.

Feynman X distributions of the K0S in LAMBDABAR K0S production from SIGMA- on C and CU targets.

Feynman X distributions of the LAMBDABAR in LAMBDABAR K0S production from PI- on C and CU targets.

Feynman X distributions of the K0S in LAMBDABAR K0S production from PI- on C and CU targets.

Feynman X distributions of the LAMBDABAR in LAMBDABAR K0S production from N on C and CU targets.

Feynman X distributions of the K0S in LAMBDABAR K0S production from N on C and CU targets.

Feynman X distributions of the first LAMBDABAR in LAMBDABAR LAMBDABAR production from SIGMA- on C and CU targets.

Feynman X distributions of the second LAMBDABAR in LAMBDABAR LAMBDABAR production from SIGMA- on C and CU targets.

Feynman X distributions of the first LAMBDABAR in LAMBDABAR LAMBDABAR production from PI- on C and CU targets.

Feynman X distributions of the second LAMBDABAR in LAMBDABAR LAMBDABAR production from PI- on C and CU targets.

Feynman X distributions of the first LAMBDABAR in LAMBDABAR LAMBDABAR production from N on C and CU targets.

Feynman X distributions of the second LAMBDABAR in LAMBDABAR LAMBDABAR production from N on C and CU targets.

Transverse momentum distributions of the first LAMBDA in LAMBDA LAMBDA production for SIGMA- on C and CU targets.

Transverse momentum distributions of the second LAMBDA in LAMBDA LAMBDA production for SIGMA- on C and CU targets.

Transverse momentum distributions of the first LAMBDA in LAMBDA LAMBDA production for PI- on C and CU targets.

Transverse momentum distributions of the second LAMBDA in LAMBDA LAMBDA production for PI- on C and CU targets.

Transverse momentum distributions of the first LAMBDA in LAMBDA LAMBDA production for N on C and CU targets.

Transverse momentum distributions of the second LAMBDA in LAMBDA LAMBDA production for N on C and CU targets.

Transverse momentum distributions of the LAMBDA in LAMBDA LAMBDABAR production for SIGMA- on C and CU targets.

Transverse momentum distributions of the LAMBDABAR in LAMBDA LAMBDABAR production for SIGMA- on C and CU targets.

Transverse momentum distributions of the LAMBDA in LAMBDA LAMBDABAR production for PI- on C and CU targets.

Transverse momentum distributions of the LAMBDABAR in LAMBDA LAMBDABAR production for PI- on C and CU targets.

Transverse momentum distributions of the LAMBDA in LAMBDA LAMBDABAR production for N on C and CU targets.

Transverse momentum distributions of the LAMBDABAR in LAMBDA LAMBDABAR production for N on C and CU targets.

Transverse momentum distributions of the LAMBDA in LAMBDA K0S production for SIGMA- on C and CU targets.

Transverse momentum distributions of the K0S in LAMBDA K0S production for SIGMA- on C and CU targets.

Transverse momentum distributions of the LAMBDA in LAMBDA K0S production for PI- on C and CU targets.

Transverse momentum distributions of the K0S in LAMBDA K0S production for PI- on C and CU targets.

Transverse momentum distributions of the LAMBDA in LAMBDA K0S production for N on C and CU targets.

Transverse momentum distributions of the K0S in LAMBDA K0S production for N on C and CU targets.

Transverse momentum distributions of the first K0S in K0S K0S production for SIGMA- on C and CU targets.

Transverse momentum distributions of the second K0S in K0S K0S production for SIGMA- on C and CU targets.

Transverse momentum distributions of the first K0S in K0S K0S production for PI- on C and CU targets.

Transverse momentum distributions of the second K0S in K0S K0S production for PI- on C and CU targets.

Transverse momentum distributions of the first K0S in K0S K0S production for N on C and CU targets.

Transverse momentum distributions of the second K0S in K0S K0S production for N on C and CU targets.

Transverse momentum distributions of the first LAMBDABAR in LAMBDABAR LAMBDABAR production for SIGMA- on C and CU targets.

Transverse momentum distributions of the second LAMBDABAR in LAMBDABAR LAMBDABAR production for SIGMA- on C and CU targets.

Transverse momentum distributions of the first LAMBDABAR in LAMBDABAR LAMBDABAR production for PI- on C and CU targets.

Transverse momentum distributions of the second LAMBDABAR in LAMBDABAR LAMBDABAR production for PI- on C and CU targets.

Transverse momentum distributions of the first LAMBDABAR in LAMBDABAR LAMBDABAR production for N on C and CU targets.

Transverse momentum distributions of the second LAMBDABAR in LAMBDABAR LAMBDABAR production for N on C and CU targets.

Transverse momentum distributions of the LAMBDABAR in LAMBDABAR K0S production for SIGMA- on C and CU targets.

Transverse momentum distributions of the K0S in LAMBDABAR K0S production for SIGMA- on C and CU targets.

Transverse momentum distributions of the LAMBDABAR in LAMBDABAR K0S production for PI- on C and CU targets.

Transverse momentum distributions of the K0S in LAMBDABAR K0S production for PI- on C and CU targets.

Transverse momentum distributions of the LAMBDABAR in LAMBDABAR K0S production for N on C and CU targets.

Transverse momentum distributions of the K0S in LAMBDABAR K0S production for N on C and CU targets.

Differential cross section for LAMBDA LAMBDA production as a function of the difference in XF between the fast (P=3,first LAMBDA) and the slow (P=4,second LAMBDA) member of the pair for N on C and CU targets.

Differential cross section for LAMBDA LAMBDA production as a function of the difference in XF between the fast (P=3,first LAMBDA) and the slow (P=4,second LAMBDA) member of the pair for PI- on C and CU targets.

Differential cross section for LAMBDA LAMBDA production as a function of the difference in XF between the fast (P=3,first LAMBDA) and the slow (P=4,second LAMBDA) member of the pair for SIGMA- on C and CU targets.

Differential cross section for LAMBDA LAMBDABAR production as a function of the difference in XF between the fast (P=3,LAMBDA) and the slow (P=4,LAMBDABAR) member of the pair for N on C and CU targets.

Differential cross section for LAMBDA LAMBDABAR production as a function of the difference in XF between the fast (P=3,LAMBDA) and the slow (P=4,LAMBDABAR) member of the pair for PI- on C and CU targets.

Differential cross section for LAMBDA LAMBDABAR production as a function of the difference in XF between the fast (P=3,LAMBDA) and the slow (P=4,LAMBDABAR) member of the pair for SIGMA- on C and CU targets.

Differential cross section for LAMBDA K0S production as a function of the difference in XF between the fast (P=3,LAMBDA) and the slow (P=4,K0S) member of the pair for N on C and CU targets.

Differential cross section for LAMBDA K0S production as a function of the difference in XF between the fast (P=3,LAMBDA) and the slow (P=4,K0S) member of the pair for PI- on C and CU targets.

Differential cross section for LAMBDA K0S production as a function of the difference in XF between the fast (P=3,LAMBDA) and the slow (P=4,K0S) member of the pair for SIGMA- on C and CU targets.

Differential cross section for LAMBDABAR LAMBDABAR production as a function of the difference in XF between the fast (P=3,first LAMBDABAR) and the slow (P=4,second LAMBDABAR) member of the pair for N on C and CU targets.

Differential cross section for LAMBDABAR LAMBDABAR production as a function of the difference in XF between the fast (P=3,first LAMBDABAR) and the slow (P=4,second LAMBDABAR) member of the pair for PI- on C and CU targets.

Differential cross section for LAMBDABAR LAMBDABAR production as a function of the difference in XF between the fast (P=3,first LAMBDABAR) and the slow (P=4,second LAMBDABAR) member of the pair for SIGMA- on C and CU targets.

Differential cross section for LAMBDABAR K0S production as a function of the difference in XF between the fast (P=3,LAMBDABAR) and the slow (P=4,K0S) member of the pair for N on C and CU targets.

Differential cross section for LAMBDABAR K0S production as a function of the difference in XF between the fast (P=3,LAMBDABAR) and the slow (P=4,K0S) member of the pair for PI- on C and CU targets.

Differential cross section for LAMBDABAR K0S production as a function of the difference in XF between the fast (P=3,LAMBDABAR) and the slow (P=4,K0S) member of the pair for SIGMA- on C and CU targets.

Differential cross section for K0S K0S production as a function of the difference in XF between the fast (P=3,first K0S) and the slow (P=4,second K0S) member of the pair for N on C and CU targets.

Differential cross section for K0S K0S production as a function of the difference in XF between the fast (P=3,first K0S) and the slow (P=4,second K0S) member of the pair for PI- on C and CU targets.

Differential cross section for K0S K0S production as a function of the difference in XF between the fast (P=3,first K0S) and the slow (P=4,second K0S) member of the pair for SIGMA- on C and CU targets.

Cross section as a function of Feynman X for F2PRIME(1525) production with SIGMA- on CU and C targets.

Cross section as a function of transverse momentum for F2PRIME(1525) production with SIGMA- on CU and C targets.

Invariant yield of electrons from heavy-flavor decays for 40-60% central collisions, versus PT.

Invariant yield of electrons from heavy-flavor decays for 60-92% central collisions, versus PT.

Invariant yield of electrons from heavy-flavor decays for minimum bias collisions, versus PT.

Nuclear modification factor of heavy-flavor electrons for PT>0.3 Gev/c as a function of Centrality (represented by the number of participants) An additional systematic error of +0.2325,-0.1587 from the measurements in P+P collisions is not included.

Nuclear modification factor of heavy-flavor electrons for PT>3.0 Gev/c as a function of Centrality (represented by the number of participants) An additional systematic error of +0.1103,-0.09038 from the measurements in P+P collisions is not included.

Nuclear modification factor of heavy-flavor electrons versus PT for 0-10% central collisions An additional systematic error of +8%,-6% due to the uncertainty on the overlap integral TAA is to add. This error has been determined using g3data, a software allowing toextract data graphically from plots.

Azimuthal amisotropy (v2) versus PT for minimum bias collisions.

Mean PT^2 value at forward rapidities : absolute value of y belongs to [1.2;2.2] The mean PT is obtained with a phenomonological fit of the J/PSI distribution in PT of the form (1/(2*PI*PT))*D(SIG)/DPT = A ( 1+(PT/B)^2)^-6 .The systematic error includes the incertainty from the maximum shape deviation permitted by the point-to-point correlated errors and from allowing the exponent of the fit fonctionto be a free parameter.

J/PSI differential cross section times dilepton branching ratio versus rapidity.

Total cross-section for J/PSI production. The value of the total cross section has been determined by fitting the rapidity distribution with many theoretical and phenomenological shapes. The systematic error quotedwas estimated from the maximum variation allowed by shifting the mid and forward rapidity data independantely by their point-to-point correlated systematic errors.There is a +- 18 nanobarn normalization error in addition to the statistical and systematical errors shown.

Mean PT^2 values at forward rapidities (absolute value of y belongs to [1.2;2.2]), for different bins of centrality.

J/PSI invariant yield versus rapidity for 0-20%, 20-40%, 40-60%, 60-92% centrality, at mid rapidity :,-0.35<y<0.35 An up/down correction, to translate each point at the center of it's relative bin, have been applied to the data.

J/PSI invariant yield versus rapidity for 0-20%, 20-40%, 40-60%, 60-92% centrality,at forward rapidities (absolute value of y belongs to [1.2;2.2]). An up/down correction, to translate each point at the center of it's relative bin, have been applied to the data.

Nuclear modification factor Raa versus transverse momentum for 0-20%, 20-40%, 40-60%, 60-92% centrality, at mid rapidities :-0.35<y<0.35. An additional +- 10% (resp. +- 10%, +- 13%, +- 28%) global uncertainty, associated with the calculation of the number of binary collisions and the J/PSI yield in p+p, is not shown for the 0-20% (resp. 20-40%,40-60%, 60-92%) centrality bin.

Nuclear modification factor Raa versus transverse momentum for 0-20%, 20-40%, 40-60%, 60-92% centrality, at forward rapidities : absolute value of y belongs to [1.2;2.2] An additional +- 10% (resp. +- 10%, +- 13%, +- 28%) global uncertainty, associated with the calculation of the number of binary collisions and the J/PSI yield in p+p, is not shown for the 0-20% (resp. 20-40%,40-60%, 60-92%) centrality bin. An up/down correction, to translate each point at the center of it's relative bin, have been applied to the data.

Nuclear modification factor Raa versus rapidity for 0-20%, 20-40%, 40-60%, 60-92% centrality, at mid rapidities :,-0.35<y<0.35. An additional +- 10% (resp. +- 10%, +- 13%, +- 28%) global uncertainty, associated with the calculation of the number of binary collisions and the J/PSI yield in p+p, is not shown for the 0-20% (resp. 20-40%,40-60%, 60-92%) centrality bin.

Nuclear modification factor Raa versus rapidity for 0-20%, 20-40%, 40-60%, 60-92% centrality, at forward rapidities : absolute value of y belongs to [1.2;2.2] An additional +- 10% (resp. +- 10%, +- 13%, +- 28%) global uncertainty, associated with the calculation of the number of binary collisions and the J/PSI yield in p+p, is not shown for the 0-20% (resp. 20-40%,40-60%, 60-92%) centrality bin.

The number of participants Npart and the nuclear modification factor Raa versus centrality at mid rapidities :,-0.35<y<0.35. An additional +- 12% global uncertainty, associated with the calculation of the number of binary collisions and the J/PSI yield in p+p, is not shown.

The number of participants Npart and the nuclear modification factor Raa versus centrality at forward rapidities : absolute value of y belongs to [1.2;2.2] An additional +- 7% global uncertainty, associated with the calculation of the number of binary collisions and the J/PSI yield in p+p, is not shown.

Ratio of nuclear modification factors RAA(forward rapidity)/RAA(mid rapidity), versus centrality. For the two most central bins, mid rapidity points have been combined to form the ratio with the forward rapidity points. See previous tables. An additional globaluncertainty of +- 14% is not included.

Inelastic cross section measured in d+Au at $\sqrt{s}$=200 GeV through $\eta \rightarrow \pi^{0} \pi^{+} \pi^{-}$

Invariant yields measured in d+Au for different centrality classes

Invariant yields measured in Au+Au for different centrality classes

Nuclear modification factor $R_{dA}$ for $\eta$ measured in d+Au for different centrality classes

Nuclear modification factor $R_{AA}(p_T)$ for $\eta$ measured in Au+Au for different centrality classes

Ratio of $\eta$ and $\pi^{0}$ measured in p+p at $\sqrt{s}$=200 GeV

Ratio of $\eta$ and $\pi^{0}$ measured in d+Au for different centrality classes

Ratio of $\eta$ and $\pi^{0}$ measured in Au+Au for different centrality classes

Invariant cross section of $\omega$ production in $p$+$p$ and $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV measured in $\omega \rightarrow \pi^0\pi^+\pi^-$ and $\omega \rightarrow \pi^0\gamma$ decay channels.

Invariant cross section of $\omega$ production in $p$+$p$ and $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV measured in $\omega \rightarrow \pi^0\pi^+\pi^-$ and $\omega \rightarrow \pi^0\gamma$ decay channels.

Invariant cross section of $\omega$ production in $p$+$p$ and $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV measured in $\omega \rightarrow \pi^0\pi^+\pi^-$ and $\omega \rightarrow \pi^0\gamma$ decay channels.

Measured $\omega/{\pi^0}$ vs $p_T$ in $p$+$p$ collisions at $\sqrt{s_{NN}}$ = 200 GeV.

Measured $\omega/{\pi^0}$ vs $p_T$ in $p$+$p$ collisions at $\sqrt{s_{NN}}$ = 200 GeV.

Measured $\omega/{\pi^0}$ vs $p_T$ in $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

Measured $\omega/{\pi^0}$ vs $p_T$ in $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

Measured $R_{dA}$ vs $p_T$ for neutral mesons in $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV for minimum bias.

Measured $R_{dA}$ vs $p_T$ for neutral mesons in $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV for minimum bias.

Measured $R_{dA}$ vs $p_T$ for neutral mesons in $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV for 0-20% centrality.

Measured $R_{dA}$ vs $p_T$ for neutral mesons in $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV for 0-20% centrality.

Reconstructed $\omega$ mass measured in the $\pi^0\pi^+\pi^-$ decay channel vs $p_T$ in $p$+$p$ collisions at $\sqrt{s_{NN}}$ = 200 GeV.

Reconstructed $\omega$ mass measured in the $\pi^0\pi^+\pi^-$ decay channel vs $p_T$ in $d$+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

$1/{N_{trig}}$ ${dN}/{d\Delta\phi}$ distributions for charge selected $\bar{p}$ and $p$ triggers both with associated $p$ for six centrality bins. Triggers have 2.5 < $p_T$ < 4.0 GeV/$c$ and associated particles have 1.8 < $p_T$ < 2.5 GeV/$c$.

$1/{N_{trig}}$ ${dN}/{d\Delta\phi}$ distributions for charge selected $\bar{p}$ and $p$ triggers both with associated $p$ for six centrality bins. Triggers have 2.5 < $p_T$ < 4.0 GeV/$c$ and associated particles have 1.8 < $p_T$ < 2.5 GeV/$c$.

$1/{N_{trig}}$ ${dN}/{d\Delta\phi}$ distributions for charge-inclusive baryon and meson triggers and associated mesons for six centrality bins. Triggers have 2.5 < $p_T$ < 4.0 GeV/$c$ and associated particles have 1.8 < $p_T$ < 2.5 GeV/$c$.

Conditional yields per trigger on the near side for charge selected and charge selected $p$ and $\bar{p}$ correlations. Triggers have 2.5 < $p_T$ < 4.0 GeV/$c$ and associated particles have 1.8 < $p_T$ < 2.5 GeV/$c$. There is an 11.4% additional normalization error on baryon associated particle points and 8.9% each on the $p$ and $\bar{p}$ associated particle points.

Conditional yields per trigger on the away side for charge selected and charge selected $p$ and $\bar{p}$ correlations. Triggers have 2.5 < $p_T$ < 4.0 GeV/$c$ and associated particles have 1.8 < $p_T$ < 2.5 GeV/$c$.

Conditional yields per trigger for baryon and meson triggers with associated mesons. Triggers have 2.5 < $p_T$ < 4.0 GeV/$c$ and associated particles have 1.8 < $p_T$ < 2.5 GeV/$c$. There is an additional 13.6% normalization error.