Two-dimensional $\Delta\phi$ vs. $\Delta\eta$ correlation functions for non-pion triggers from 0-10% most-central Au+Au data at 200 GeV. All trigger and associated charged hadrons are selected in the respective pT ranges 4 < $p_T^{trig}$ < 5 GeV/c and 1.5 < $p_T^{assoc}$ < 4 GeV/c.

Two-dimensional $\Delta\phi$ vs. $\Delta\eta$ correlation functions for pion triggers from minimum-bias d+Au data at 200 GeV. All trigger and associated charged hadrons are selected in the respective pT ranges 4 < $p_T^{trig}$ < 5 GeV/c and 1.5 < $p_T^{assoc}$ < 4 GeV/c.

Two-dimensional $\Delta\phi$ vs. $\Delta\eta$ correlation functions for pion triggers from 0-10% most-central Au+Au data at 200 GeV. All trigger and associated charged hadrons are selected in the respective pT ranges 4 < $p_T^{trig}$ < 5 GeV/c and 1.5 < $p_T^{assoc}$ < 4 GeV/c.

The $\Delta\phi$ projections of the pure-cone correlations for |$\Delta\phi$| < $\pi$/4 for pion triggers.

The $\Delta\eta$ projections of the pure-cone correlations for |$\Delta\eta$| < 0.78 for pion triggers.

The $\Delta\phi$ projections of the pure-cone correlations for |$\Delta\phi$| < $\pi$/4 non-pion triggers.

The $\Delta\eta$ projections of the pure-cone correlations for |$\Delta\eta$| < 0.78 non-pion triggers.

$\Delta\phi$ projections over |$\Delta\eta$| < 1.5 in 0-10% Au+Au and minimum-bias d+Au data at 200 GeV after subtracting the jet-like fit components.

Extracted Fourier coefficients from fitting in $\pi$ 2 < $\Delta\phi$ < 3$\pi/2$ ) x (|$\Delta\eta$| < 1.5) (1.52 for d+Au), for pion, non-pion, and charged hadron triggers in the flow-based model.

Extracted Fourier coefficients from fitting in $\pi$ 2 < $\Delta\phi$ < 3$\pi/2$ ) x (|$\Delta\eta$| < 1.5) (1.52 for d+Au), for pion, non-pion, and charged hadron triggers in the flow-based model.

V3/V2 ratio for pion and non-pion triggers in Au+Au, and the extrapolated value for "pure protons".

The $V_2${2} and difference between the pairs at ($\eta_{\alpha}$, $\eta_{\beta}$) and ($\eta_{\alpha}$, -$\eta_{\beta}$). The data are from 20-30% central Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

The $V_2${2} and difference between the pairs at ($\eta_{\alpha}$, $\eta_{\beta}$) and ($\eta_{\alpha}$, -$\eta_{\beta}$). The data are from 20-30% central Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

The $V_2${2} and difference between the pairs at ($\eta_{\alpha}$, $\eta_{\beta}$) and ($\eta_{\alpha}$, -$\eta_{\beta}$). The data are from 20-30% central Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

The $V_2${2} and difference between the pairs at ($\eta_{\alpha}$, $\eta_{\beta}$) and ($\eta_{\alpha}$, -$\eta_{\beta}$). The data are from 20-30% central Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

The $V_3${2} and difference between the pairs at ($\eta_{\alpha}$, $\eta_{\beta}$) and ($\eta_{\alpha}$, -$\eta_{\beta}$). The data are from 20-30% central Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

The $V_3${2} and difference between the pairs at ($\eta_{\alpha}$, $\eta_{\beta}$) and ($\eta_{\alpha}$, -$\eta_{\beta}$). The data are from 20-30% central Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

The $V_3${2} and difference between the pairs at ($\eta_{\alpha}$, $\eta_{\beta}$) and ($\eta_{\alpha}$, -$\eta_{\beta}$). The data are from 20-30% central Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

The $V_3${2} and difference between the pairs at ($\eta_{\alpha}$, $\eta_{\beta}$) and ($\eta_{\alpha}$, -$\eta_{\beta}$). The data are from 20-30% central Au+Au collisions at $\sqrt{s_{NN}}$ = 200 GeV.

The $V_2^{1/2}$ difference between quadruplets at ($\eta_{\alpha}$, $\eta_{\alpha}$, $\eta_{\beta}$, $\eta_{\beta}$) and ($\eta_{\alpha}$, $\eta_{\alpha}$, -$\eta_{\beta}$, -$\eta_{\beta}$).

The two-particle cumulants, V2{2} as a function of $\eta$ for one particle while averaged over $\eta$ of the partner particle.

The two-particle cumulants, V2{2} as a function of $\eta$.

The two-particle cumulants, V2{2} as a function of $\eta$ for one particle while averaged over $\eta$ of the partner particle.

The difference in two-particle cumulants, V2{2} as a function of $\eta$ for one particle while averaged over $\eta$ of the partner particle.

No description provided.

V3{2} as a function of $\eta$.

<$V_3^2$> as a function of $\eta$.

The $\Delta\eta$-dependent component of the two-particle cumulant with $\Delta\eta$-gap, $D^-$ in Eq. (11), of the second harmonic is shown as a function of ??-gap |$\Delta\eta$| > x.

The $\Delta\eta$-dependent component of the two-particle cumulant with $\Delta\eta$-gap, $D^-$ in Eq. (11), of the third harmonic is shown as a function of ??-gap |$\Delta\eta$| > x.

The nonflow, $\sqrt{\bar{D}_2}$, $\sqrt{\delta_2}$, $\sqrt{\bar{D}_3}$ and flow, $\sqrt{v_2^2/2}$, $\sqrt{<v_2^2>}$ results are shown as a function of centrality percentile for the second harmonic.

The nonflow, $\sqrt{\bar{D}_2}$, $\sqrt{\delta_2}$, $\sqrt{\bar{D}_3}$ and flow, $\sqrt{v_2^2/2}$, $\sqrt{<v_2^2>}$ results are shown as a function of centrality percentile for the second harmonic.

The nonflow, $\sqrt{\bar{D}_2}$, $\sqrt{\delta_2}$, $sqrt{\bar{D}_3}$ and flow, $\sqrt{v_2^2/2}$, $\sqrt{<v_2^2>}$ results are shown as a function of centrality percentile for the second harmonic.

The nonflow, $\sqrt{\bar{D}_2}$, $\sqrt{\delta_2}$, $sqrt{\bar{D}_3}$ and flow, $\sqrt{v_2^2/2}$, $\sqrt{<v_2^2>}$ results are shown as a function of centrality percentile for the third harmonic.

The nonflow, $\sqrt{\bar{D}_2}$, $sqrt{\delta_2}$, $\sqrt{\bar{D}_3}$ and flow, $\sqrt{v_2^2/2}$, $\sqrt{<v_2^2>}$ results are shown as a function of centrality percentile for the third harmonic.

The relative elliptic flow fluctuation $\sigma_2/<v_2>$ centrality dependence in $\sqrt{s_{NN}}$ = 200 GeV Au+Au collisions.

The experimental sensitivity and observed limit on the number of dark photon candidates as a function of the assumed dark photon mass.

Limits on the $U-\gamma$ mixing parameters from PHENIX at 90%, 85% and 80% confidence levels.

The $v_{dyn}$ and the three terms of $v_{dyn}$ vs $\sqrt{\langle N_{ch}\rangle \langle N_{\gamma}\rangle }$ for mixed events. $Corr_{\gamma\,-ch}^{real}$ is plotted.

The $v_{dyn}$ and the three terms of $v_{dyn}$ vs $\sqrt{\langle N_{ch}\rangle \langle N_{\gamma}\rangle }$ for mixed events. $Corr_{\gamma\,-ch}^{mixed}$ is plotted.

The $v_{dyn}$ and the three terms of $v_{dyn}$ vs $\sqrt{\langle N_{ch}\rangle \langle N_{\gamma}\rangle }$ for mixed events. $\omega_{\gamma}^{real}$ is plotted.

The $v_{dyn}$ and the three terms of $v_{dyn}$ vs $\sqrt{\langle N_{ch}\rangle \langle N_{\gamma}\rangle }$ for mixed events. $\omega_{\gamma}^{mixed}$ is plotted.

The $v_{dyn}$ and the three terms of $v_{dyn}$ vs $\sqrt{\langle N_{ch}\rangle \langle N_{\gamma}\rangle }$ for mixed events. $v_{dyn}^{real}$ is plotted.

The $v_{dyn}$ and the three terms of $v_{dyn}$ vs $\sqrt{\langle N_{ch}\rangle \langle N_{\gamma}\rangle }$ for mixed events. $v_{dyn}^{mixed}$ is plotted.

The values of the observable $v_{dyn}^{ch-\gamma}$ for the same side.

The values of the observable $v_{dyn}^{ch-\gamma}$ for the same side.

The values of the observable $v_{dyn}^{ch-\gamma}$ for the away-side.

The values of the observable $v_{dyn}^{ch-\gamma}$ for the away-side.

The correlation between positive and negative charged particles measured by the FTPC and photons measured by the PMD using $v_{dyn}$ for real events.

$r_{m,1}$ vs multiplicity for first order of m.

$r_{m,1}$ vs multiplicity for first order of m.

$r_{m,1}$ vs multiplicity for second order of m.

$r_{m,1}$ vs multiplicity for second order of m.

$r_{m,1}$ vs multiplicity for third order of m.

$r_{m,1}$ vs multiplicity for third order of m.

The moments $r_{m,1}$(m=1-3) for real and mixed events as a function of order m in a fixed multiplicity bin of 47$\langle \sqrt{\langle N_{ch}\rangle \langle N_{\gamma}\rangle }\langle 54$.

The $\Lambda\Lambda$ interaction parameters from this experiment.

Target asymmetry T for c.m. energy W= 1.5584 GeV

Target asymmetry T for c.m. energy W= 1.5882 GeV

Target asymmetry T for c.m. energy W= 1.6175 GeV

Target asymmetry T for c.m. energy W= 1.6462 GeV

Target asymmetry T for c.m. energy W= 1.6745 GeV

Target asymmetry T for c.m. energy W= 1.7022 GeV

Target asymmetry T for c.m. energy W= 1.7431 GeV

Target asymmetry T for c.m. energy W= 1.7961 GeV

Target asymmetry T for c.m. energy W= 1.8476 GeV

Beam-target asymmetry F for c.m. energy W= 1.4969 GeV

Beam-target asymmetry F for c.m. energy W= 1.5156 GeV

Beam-target asymmetry F for c.m. energy W= 1.5341 GeV

Beam-target asymmetry F for c.m. energy W= 1.5584 GeV

Beam-target asymmetry F for c.m. energy W= 1.5882 GeV

Beam-target asymmetry F for c.m. energy W= 1.6175 GeV

Beam-target asymmetry F for c.m. energy W= 1.6462 GeV

Beam-target asymmetry F for c.m. energy W= 1.6745 GeV

Beam-target asymmetry F for c.m. energy W= 1.7022 GeV

Beam-target asymmetry F for c.m. energy W= 1.7431 GeV

Beam-target asymmetry F for c.m. energy W= 1.7961 GeV

Beam-target asymmetry F for c.m. energy W= 1.8476 GeV

Differential cross section at W= 1.4975 GeV

Differential cross section at W= 1.5025 GeV

Differential cross section at W= 1.5075 GeV

Differential cross section at W= 1.5125 GeV

Differential cross section at W= 1.5175 GeV

Differential cross section at W= 1.5225 GeV

Differential cross section at W= 1.5275 GeV

Differential cross section at W= 1.5325 GeV

Differential cross section at W= 1.5375 GeV

Differential cross section at W= 1.5450 GeV

Differential cross section at W= 1.5550 GeV

Differential cross section at W= 1.5650 GeV

Differential cross section at W= 1.5750 GeV

Differential cross section at W= 1.5850 GeV

Differential cross section at W= 1.5950 GeV

Differential cross section at W= 1.6050 GeV

Differential cross section at W= 1.6150 GeV

Differential cross section at W= 1.6250 GeV

Differential cross section at W= 1.6350 GeV

Differential cross section at W= 1.6450 GeV

Differential cross section at W= 1.6550 GeV

Differential cross section at W= 1.6650 GeV

Differential cross section at W= 1.6750 GeV

Differential cross section at W= 1.6850 GeV

Differential cross section at W= 1.6950 GeV

Differential cross section at W= 1.7050 GeV

Differential cross section at W= 1.7150 GeV

Differential cross section at W= 1.7250 GeV

Differential cross section at W= 1.7350 GeV

Differential cross section at W= 1.7450 GeV

Differential cross section at W= 1.7550 GeV

Differential cross section at W= 1.7650 GeV

Differential cross section at W= 1.7750 GeV

Differential cross section at W= 1.7850 GeV

Differential cross section at W= 1.7950 GeV

Differential cross section at W= 1.8050 GeV

Differential cross section at W= 1.8150 GeV

Differential cross section at W= 1.8250 GeV

Differential cross section at W= 1.8350 GeV

Differential cross section at W= 1.8450 GeV

Differential cross section at W= 1.8550 GeV

Differential cross section at W= 1.8650 GeV

Differential cross section at W= 1.8750 GeV

Differential cross section at W= 1.4925 GeV

Differential cross section at W= 1.4975 GeV

Differential cross section at W= 1.5025 GeV

Differential cross section at W= 1.5075 GeV

Differential cross section at W= 1.5125 GeV

Differential cross section at W= 1.5175 GeV

Differential cross section at W= 1.5225 GeV

Differential cross section at W= 1.5275 GeV

Differential cross section at W= 1.5325 GeV

Differential cross section at W= 1.5375 GeV

Differential cross section at W= 1.5450 GeV

Differential cross section at W= 1.5550 GeV

Differential cross section at W= 1.5650 GeV

Differential cross section at W= 1.5750 GeV

Differential cross section at W= 1.5850 GeV

Differential cross section at W= 1.5950 GeV

Differential cross section at W= 1.6050 GeV

Differential cross section at W= 1.6150 GeV

Differential cross section at W= 1.6250 GeV

Differential cross section at W= 1.6350 GeV

Differential cross section at W= 1.6450 GeV

Differential cross section at W= 1.6550 GeV

Differential cross section at W= 1.6650 GeV

Differential cross section at W= 1.6750 GeV

Differential cross section at W= 1.6850 GeV

Differential cross section at W= 1.6950 GeV

Differential cross section at W= 1.7050 GeV

Differential cross section at W= 1.7150 GeV

Differential cross section at W= 1.7250 GeV

Differential cross section at W= 1.7350 GeV

Differential cross section at W= 1.7450 GeV

Differential cross section at W= 1.7550 GeV

Differential cross section at W= 1.7650 GeV

Differential cross section at W= 1.7750 GeV

Differential cross section at W= 1.7850 GeV

Differential cross section at W= 1.7950 GeV

Differential cross section at W= 1.8050 GeV

Differential cross section at W= 1.8150 GeV

Differential cross section at W= 1.8250 GeV

Differential cross section at W= 1.8350 GeV

Differential cross section at W= 1.8450 GeV

Differential cross section at W= 1.8550 GeV

Differential cross section at W= 1.8650 GeV

Differential cross section at W= 1.8750 GeV

Differential cross section at W= 1.7401 GeV

Differential cross section at W= 1.7490 GeV

Differential cross section at W= 1.7568 GeV

Differential cross section at W= 1.7645 GeV

Differential cross section at W= 1.7729 GeV

Differential cross section at W= 1.7811 GeV

Differential cross section at W= 1.7891 GeV

Differential cross section at W= 1.7968 GeV

Differential cross section at W= 1.8045 GeV

Differential cross section at W= 1.8119 GeV

Differential cross section at W= 1.8192 GeV

Differential cross section at W= 1.8269 GeV

Differential cross section at W= 1.8348 GeV

Differential cross section at W= 1.8424 GeV

Differential cross section at W= 1.8504 GeV

Differential cross section at W= 1.8581 GeV

Differential cross section at W= 1.8657 GeV

Differential cross section at W= 1.8720 GeV

The 23 unpolarized and polarized $\omega$ SDMEs for the deuteron data in $Q^2$ intervals: $1.00 - 1.57 - 2.55 - 10.00$ GeV$^2$.

The 23 unpolarized and polarized $\omega$ SDMEs for the deuteron data in $-t'$ intervals: $0.000 - 0.044 - 0.105 - 0.200$ GeV$^2$.

The 23 unpolarized and polarized $\omega$ SDMEs in the Diehl representation for proton and deuteron data in the entire kinematic region.

The definition of intervals and the mean values for kinematic variables.

The correlation matrix for the 23 SDMEs obtained from the hydrogen target data.

The correlation matrix for the 23 SDMEs obtained from the deuterium target data.