Measured value of TT and LT polarized cross sections extracted from the data.

Values of r_04_00 and r_1_1-1 extracted from the angular distributions.

Lower Q**2 extracted differential cross section at W = 1.500 GeV and cos(theta(eta) = -0.417, -0.250 and -0.083.

Lower Q**2 extracted differential cross section at W = 1.500 GeV and cos(theta(eta) = 0.083, 0.250 and 0.417.

Lower Q**2 extracted differential cross section at W = 1.500 GeV and cos(theta(eta) = 0.583, 0.750 and 0.917.

Lower Q**2 extracted differential cross section at W = 1.530 GeV and cos(theta(eta) = -0.917, -0.750 and -0.583.

Lower Q**2 extracted differential cross section at W = 1.530 GeV and cos(theta(eta) = -0.417, -0.250 and -0.083.

Lower Q**2 extracted differential cross section at W = 1.530 GeV and cos(theta(eta) = 0.083, 0.250 and 0.417.

Lower Q**2 extracted differential cross section at W = 1.530 GeV and cos(theta(eta) = 0.583, 0.750 and 0.917.

Lower Q**2 extracted differential cross section at W = 1.560 GeV and cos(theta(eta) = -0.917, -0.750 and -0.583.

Lower Q**2 extracted differential cross section at W = 1.560 GeV and cos(theta(eta) = -0.417, -0.250 and -0.083.

Lower Q**2 extracted differential cross section at W = 1.560 GeV and cos(theta(eta) = 0.083, 0.250 and 0.417.

Lower Q**2 extracted differential cross section at W = 1.560 GeV and cos(theta(eta) = 0.583, 0.750 and 0.917.

Lower Q**2 extracted differential cross section at W = 1.590 GeV and cos(theta(eta) = -0.917, -0.750 and -0.583.

Lower Q**2 extracted differential cross section at W = 1.590 GeV and cos(theta(eta) = -0.417, -0.250 and -0.083.

Lower Q**2 extracted differential cross section at W = 1.590 GeV and cos(theta(eta) = 0.083, 0.250 and 0.417.

Lower Q**2 extracted differential cross section at W = 1.590 GeV and cos(theta(eta) = 0.583, 0.750 and 0.917.

Lower Q**2 extracted differential cross section at W = 1.625 GeV and cos(theta(eta) = -0.917, -0.750 and -0.583.

Lower Q**2 extracted differential cross section at W = 1.625 GeV and cos(theta(eta) = -0.417, -0.250 and -0.083.

Lower Q**2 extracted differential cross section at W = 1.625 GeV and cos(theta(eta) = 0.083, 0.250 and 0.417.

Lower Q**2 extracted differential cross section at W = 1.625 GeV and cos(theta(eta) = 0.583, 0.750 and 0.917.

Lower Q**2 extracted differential cross section at W = 1.665 GeV and cos(theta(eta) = -0.917, -0.750 and -0.583.

Lower Q**2 extracted differential cross section at W = 1.665 GeV and cos(theta(eta) = -0.417, -0.250 and -0.083.

Lower Q**2 extracted differential cross section at W = 1.705 GeV and cos(theta(eta) = -0.917, -0.750 and -0.583.

Lower Q**2 extracted differential cross section at W = 1.745 GeV and cos(theta(eta) = -0.917, -0.750 and -0.583.

Lower Q**2 extracted differential cross section at W = 1.785 GeV and cos(theta(eta) = -0.917, -0.750 and -0.583.

Lower Q**2 extracted differential cross section at W = 1.830 GeV and cos(theta(eta) = -0.917, -0.750 and -0.583.

Higher Q**2 extracted differential cross section at W = 1.500 GeV and cos(theta(eta) = -0.833 and -0.500.

Higher Q**2 extracted differential cross section at W = 1.500 GeV and cos(theta(eta) = -0.167 and 0.167.

Higher Q**2 extracted differential cross section at W = 1.530 GeV and cos(theta(eta) = -0.833 and -0.500.

Higher Q**2 extracted differential cross section at W = 1.530 GeV and cos(theta(eta) = -0.167 and 0.167.

Higher Q**2 extracted differential cross section at W = 1.560 GeV and cos(theta(eta) = -0.833 and -0.500.

Higher Q**2 extracted differential cross section at W = 1.560 GeV and cos(theta(eta) = -0.167 and 0.167.

Higher Q**2 extracted differential cross section at W = 1.592 GeV and cos(theta(eta) = -0.833 and -0.500.

Higher Q**2 extracted differential cross section at W = 1.592 GeV and cos(theta(eta) = -0.167 and 0.167.

Higher Q**2 extracted differential cross section at W = 1.635 GeV and cos(theta(eta) = -0.833 and -0.500.

Higher Q**2 extracted differential cross section at W = 1.685 GeV and cos(theta(eta) = -0.833 and -0.500.

Higher Q**2 extracted differential cross section at W = 1.740 GeV and cos(theta(eta) = -0.833 and -0.500.

Differential cross section for the region ABS(YRAP(JET)) 1.5 to 2.5 and YRAP(GAMMA)*YRAP(JET) < 0.

Ratio of the differential cross section in the region ABS(YRAP(JET)) < 0.8 and YRAP(GAMMA)*YRAP(JET) < 0 to the region ABS(YRAP(JET)) < 0.8 and YRAP(GAMMA)*YRAP(JET) > 0.

Ratio of the differential cross section in the region ABS(YRAP(JET)) < 0.8 and YRAP(GAMMA)*YRAP(JET) > 0 to the region ABS(YRAP(JET)) 1.5 TO 2.5 and YRAP(GAMMA)*YRAP(JET) > 0.

Ratio of the differential cross section in the region ABS(YRAP(JET)) < 0.8 and YRAP(GAMMA)*YRAP(JET) < 0 to the region ABS(YRAP(JET)) 1.5 TO 2.5 and YRAP(GAMMA)*YRAP(JET) > 0.

Ratio of the differential cross section in the region ABS(YRAP(JET)) 1.5 TO 2.5 and YRAP(GAMMA)*YRAP(JET) < 0 to the region ABS(YRAP(JET)) 1.5 TO 2.5 and YRAP(GAMMA)*YRAP(JET) > 0.

Ratio of the differential cross section in the region ABS(YRAP(JET)) < 0.8 and YRAP(GAMMA)*YRAP(JET) > 0 to the region ABS(YRAP(JET)) 1.5 TO 2.5 and YRAP(GAMMA)*YRAP(JET) < 0.

Ratio of the differential cross section in the region ABS(YRAP(JET)) < 0.8 and YRAP(GAMMA)*YRAP(JET) < 0 to the region ABS(YRAP(JET)) 1.5 TO 2.5 and YRAP(GAMMA)*YRAP(JET) < 0.

FIG. 1: (a) Raw two-particle correlation signal $Y_2$ (red), background $aB_{inc}F_2$ (solid histogram), and background systematic uncertainty from a (dashed histograms). (b) Background-subtracted two-particle correlation $\hat{Y}_2$ (red), and systematic uncertainties due to a (dashed histograms) and flow (blue histograms). (c) Raw three-particle correlation $Y_3$. (d) $ba^2Y_{inc}^2$ . (e) Sum of trig-corr-bkgd and trigger flow. Data are from 12% central Au+Au collisions. Statistical errors in (a,b) are smaller than the point size.

FIG. 1: (a) Raw two-particle correlation signal $Y_2$ (red), background $aB_{inc}F_2$ (solid histogram), and background systematic uncertainty from a (dashed histograms). (b) Background-subtracted two-particle correlation $\hat{Y}_2$ (red), and systematic uncertainties due to a (dashed histograms) and flow (blue histograms). (c) Raw three-particle correlation $Y_3$. (d) $ba^2Y_{inc}^2$ . (e) Sum of trig-corr-bkgd and trigger flow. Data are from 12% central Au+Au collisions. Statistical errors in (a,b) are smaller than the point size.

FIG. 2: Background subtracted three-particle correlations, $\hat{Y}_3$, for (a) pp, (b) d+Au, (c) 80-50% Au+Au, (d) 50-30% Au+Au, (e) 30-10% Au+Au, and (f) 12% central Au+Au. Statistical errors per bin are approximately $\pm$0.012 in (a) and $\pm$0.006 in (b), both at ($\pi$, $\pi$), and are $\pm$0.022, $\pm$0.049, $\pm$0.099 and $\pm$0.077 from (c) to (f), similar for all bins.

FIG. 2: Background subtracted three-particle correlations, $\hat{Y}_3$, for (a) pp, (b) d+Au, (c) 80-50% Au+Au, (d) 50-30% Au+Au, (e) 30-10% Au+Au, and (f) 12% central Au+Au. Statistical errors per bin are approximately $\pm$0.012 in (a) and $\pm$0.006 in (b), both at ($\pi$, $\pi$), and are $\pm$0.022, $\pm$0.049, $\pm$0.099 and $\pm$0.077 from (c) to (f), similar for all bins.

FIG. 2: Background subtracted three-particle correlations, $\hat{Y}_3$, for (a) pp, (b) d+Au, (c) 80-50% Au+Au, (d) 50-30% Au+Au, (e) 30-10% Au+Au, and (f) 12% central Au+Au. Statistical errors per bin are approximately $\pm$0.012 in (a) and $\pm$0.006 in (b), both at ($\pi$, $\pi$), and are $\pm$0.022, $\pm$0.049, $\pm$0.099 and $\pm$0.077 from (c) to (f), similar for all bins.

FIG. 2: Background subtracted three-particle correlations, $\hat{Y}_3$, for (a) pp, (b) d+Au, (c) 80-50% Au+Au, (d) 50-30% Au+Au, (e) 30-10% Au+Au, and (f) 12% central Au+Au. Statistical errors per bin are approximately $\pm$0.012 in (a) and $\pm$0.006 in (b), both at ($\pi$, $\pi$), and are $\pm$0.022, $\pm$0.049, $\pm$0.099 and $\pm$0.077 from (c) to (f), similar for all bins.

FIG. 2: Background subtracted three-particle correlations, $\hat{Y}_3$, for (a) pp, (b) d+Au, (c) 80-50% Au+Au, (d) 50-30% Au+Au, (e) 30-10% Au+Au, and (f) 12% central Au+Au. Statistical errors per bin are approximately $\pm$0.012 in (a) and $\pm$0.006 in (b), both at ($\pi$, $\pi$), and are $\pm$0.022, $\pm$0.049, $\pm$0.099 and $\pm$0.077 from (c) to (f), similar for all bins.

FIG. 2: Background subtracted three-particle correlations, $\hat{Y}_3$, for (a) pp, (b) d+Au, (c) 80-50% Au+Au, (d) 50-30% Au+Au, (e) 30-10% Au+Au, and (f) 12% central Au+Au. Statistical errors per bin are approximately $\pm$0.012 in (a) and $\pm$0.006 in (b), both at ($\pi$, $\pi$), and are $\pm$0.022, $\pm$0.049, $\pm$0.099 and $\pm$0.077 from (c) to (f), similar for all bins.

Projections of away-side three-particle correlations along the diagonal $\Sigma$ within 0 < $\Delta$ < 0.35 (squares) and along the off-diagonal $\Delta$ within |$\Sigma$| < 0.35 (points) in (a) d+Au and (b) 12% central Au+Au collisions. The shaded areas indicate systematic uncertainties on the off-diagonal projections. The histogram in (a) is the near-side off-diagonal projection. The histogram in (b) is the away-side off-diagonal projection of our result with a = b = 1. NOTE: For points with invisible error bars, the point size was considered as an absolute upper limit for the uncertainty.

Projections of away-side three-particle correlations along the diagonal $\Sigma$ within 0 < $\Delta$ < 0.35 (squares) and along the off-diagonal $\Delta$ within |$\Sigma$| < 0.35 (points) in (a) d+Au and (b) 12% central Au+Au collisions. The shaded areas indicate systematic uncertainties on the off-diagonal projections. The histogram in (a) is the near-side off-diagonal projection. The histogram in (b) is the away-side off-diagonal projection of our result with a = b = 1. NOTE: For points with invisible error bars, the point size was considered as an absolute upper limit for the uncertainty.

Three-particle correlation strength per radian$^2$ versus ($N_{part}$/2)$^{1/3}$ where $N_{part}$ is the number of participants. Some of the data points have been displaced in $N_{part}$ for clarity.

(Color online) Dynamical net charge fluctuations, $\nu_{+−,dyn}$, of particles produced with pseudorapidity $|\eta|$ < 0.5 scaled by (a) the multiplicity, $dN_{ch}/d\eta$. The dashed line corresponds to charge conservation effect and the solid line to the prediction for a resonance gas, (b) the number of participants, and (c) the number of binary collisions.

(Color online) Dynamical net charge fluctuations, $\nu_{+−,dyn}$, of particles produced with pseudorapidity $|\eta|$ < 0.5 scaled by (a) the multiplicity, $dN_{ch}/d\eta$. The dashed line corresponds to charge conservation effect and the solid line to the prediction for a resonance gas, (b) the number of participants, and (c) the number of binary collisions.

(Color online) Dynamical fluctuations $\nu_{+−,dyn}$, normalized to their value for |$\eta$| < 1, as function of the integrated pseudorapidity range. (a) data for $Au + Au$ collisions at $\sqrt{s_{NN}}$ = 62.4, 200 GeV (0-5%) along with data for $Cu + Cu$ collisions at $\sqrt{s_{NN}}$ = 62.4, 200 GeV (0-10%), are compared to inclusive $p + p$ data at $\sqrt{s}$ = 200 GeV, and (b) data for $Au + Au$ collisions at $\sqrt{s_{NN}}$ = 62.4, 200 GeV (30-40%) along with data for $Cu + Cu$ collisions at $\sqrt{s_{NN}}$ = 62.4, 200 GeV (0-10%), are compared to inclusive $p + p$ collision data at $\sqrt{}s$ = 200 GeV.

(Color online) Dynamical fluctuations $\nu_{+−,dyn}$, normalized to their value for |$\eta$| < 1, as function of the integrated pseudorapidity range. (a) data for $Au + Au$ collisions at $\sqrt{s_{NN}}$ = 62.4, 200 GeV (0-5%) along with data for $Cu + Cu$ collisions at $\sqrt{s_{NN}}$ = 62.4, 200 GeV (0-10%), are compared to inclusive $p + p$ data at $\sqrt{s}$ = 200 GeV, and (b) data for $Au + Au$ collisions at $\sqrt{s_{NN}}$ = 62.4, 200 GeV (30-40%) along with data for $Cu + Cu$ collisions at $\sqrt{s_{NN}}$ = 62.4, 200 GeV (0-10%), are compared to inclusive $p + p$ collision data at $\sqrt{}s$ = 200 GeV.

(Color online) Dynamical fluctuations $\nu_{+−,dyn}$, as a function of the integrated azimuthal range $\phi$ for selected collision centralities for (a) $Au + Au$ collisions at $\sqrt{s_{NN}}$ = 200 GeV, and (b) $Cu + Cu$ collisions at $\sqrt{s_{NN}}$ = 200 GeV.

(Color online) Dynamical fluctuations $\nu_{+−,dyn}$, as a function of the integrated azimuthal range $\phi$ for selected collision centralities for (a) $Au + Au$ collisions at $\sqrt{s_{NN}}$ = 200 GeV, and (b) $Cu + Cu$ collisions at $\sqrt{s_{NN}}$ = 200 GeV.

(Color online) Dynamical fluctuations $\nu_{+−,dyn}$, as a function of the integrated azimuthal range $\phi$ for similar number of participating nucleons for $Au + Au$ and $Cu + Cu$ $\sqrt{s_{NN}}$ = 200 GeV.

Charged particle $v_1(\eta)$ for 40-80 % centrality in Au+Au collisions at 200 GeV.

Charged particle $v_1(p_t)$ in 200 GeV Au+Au for three centralities and two pseudorapidity ranges.

Charged particle $v_1(\eta)$ for mid-central (30-60%) Au+Au and Cu+Cu collisions at 200 GeV and 62.4 GeV.

Charged particle $v_1$ versus centrality for Au+Au and Cu+Cu collisions at 200 GeV and 62.4 GeV in two pseudorapidity ranges.

Charged particle $v_1$ versus $\eta-y_{beam}$, for 30 − 60% Au+Au collisions at 200 GeV.

Charged particle $v_1$ versus $\eta-y_{beam}$, for 30 − 60% Cu+Cu collisions at 200 GeV.

Charged particle $v_1$ versus $\eta-y_{beam}$, for 30 − 60% Au+Au collisions at 62.4 GeV.

Charged particle $v_1$ versus $\eta-y_{beam}$, for 30 − 60% Cu+Cu collisions at 62.4 GeV.