Net-proton cumulant ratios, (a) $C_{2}/C_{1}$, (b) $C_{3}/C_{2}$, (c) $C_{4}/C_{2}$, (d) $C_{5}/C_{1}$, and (e) $C_{6}/C_{2}$ as a function of charged-particle multiplicity from $\sqrt{s}=200$ GeV $p$+$p$ collisions. Black solid lines and red bands represent the statistical and systematic uncertainties, respectively. Cyan points represent event averages for $3 < m_{\rm ch}^{\rm TPC} < 30$, and they are plotted at the corresponding value of $m_{\rm ch}^{\rm TPC}$. The uncertainties on the cyan points are smaller than the marker size. The Skellam baselines are shown as dotted lines. The results of the PYTHIA8 calculations are shown by hatched-golden bands. The golden bands at $m_{\rm ch}^{\rm TPC}\approx 6$ are the results from the PYTHIA8 calculations averaged over multiplicities.

Rapidity-acceptance dependence of the net-proton cumulant ratios, (a) $C_{4}/C_{2}$, (b) $C_{5}/C_{1}$, and (c) $C_{6}/C_{2}$ shown as a function of the charged-particle multiplicity, $m_{\rm ch}^{\rm TPC}$, from $\sqrt{s}=200$ GeV $p$+$p$ collisions. Solid squares, triangles, and circles represent the results with $|y|<0.1$, $0.3$, and $0.5$, respectively. Black solid lines and colored bands show the statistical and systematic uncertainties.The data points and their uncertainties for $|y|<0.1$ and $0.3$ are slightly shifted for clarity. The Skellam baselines are shown by dotted lines.

Net-proton cumulant ratios, (a) $C_{4}/C_{2}$, (b) $C_{5}/C_{1}$, and (c) $C_{6}/C_{2}$ as a function of charged-particle multiplicity for $p$+$p$ collisions and Au+Au collisions at 200 GeV for $|y|<0.5$ and $0.4<p_{\rm T}<2.0$ GeV/$c$. Cyan markers represent event averages for $3<m_{\rm ch}^{\rm TPC}<30$ from the $p$+$p$ collisions. Results from Au+Au collisions are shown as triangles for the 0-40%, 40-50%, 50-60%, 60-70%, and 70-80% centrality bins. Red and grey bands show the systematic uncertainties for $p$+$p$ collisions and Au+Au collisions, respectively. The $m_{\rm ch}^{\rm TPC}$ values are not corrected for the reconstruction efficiency of the TPC. The golden bands at $m_{\rm ch}^{\rm TPC}\approx 6$ represent the results from PYTHIA8 calculations averaged over multiplicity. The Skellam baselines are shown in dotted lines. The purple bands show corresponding susceptibility ratios of baryon number from lattice QCD calculations, where the multiplicity range is chosen arbitrary.

Net-proton cumulant ratios, (a) $C_{4}/C_{2}$, (b) $C_{5}/C_{1}$, and (c) $C_{6}/C_{2}$ as a function of charged-particle multiplicity for $p$+$p$ collisions and Au+Au collisions at 200 GeV for $|y|<0.5$ and $0.4<p_{\rm T}<2.0$ GeV/$c$. Cyan markers represent event averages for $3<m_{\rm ch}^{\rm TPC}<30$ from the $p$+$p$ collisions. Results from Au+Au collisions are shown as triangles for the 0-40%, 40-50%, 50-60%, 60-70%, and 70-80% centrality bins. Red and grey bands show the systematic uncertainties for $p$+$p$ collisions and Au+Au collisions, respectively. The $m_{\rm ch}^{\rm TPC}$ values are not corrected for the reconstruction efficiency of the TPC. The golden bands at $m_{\rm ch}^{\rm TPC}\approx 6$ represent the results from PYTHIA8 calculations averaged over multiplicity. The Skellam baselines are shown in dotted lines. The purple bands show corresponding susceptibility ratios of baryon number from lattice QCD calculations, where the multiplicity range is chosen arbitrary.

Mass dependence of the mid-rapidity $v_1$ slope, $dv_1/dy$, for $\Lambda$, $^{3}_{\Lambda}$H and $^{4}_{\Lambda}$H from the $\sqrt{s_{NN}}$ = 3 GeV 5-40% mid-central Au+Au collisions. The statistical and systematic uncertainties are presented by vertical lines and square brackets, respectively. The slopes of $p$, $d$, $t$, $^3$He and $^4$He from the same collisions are shown as black circles. The blue and dashed green lines are the results of a linear fit to the measured light nuclei and hypernuclei $v_1$ slopes, respectively. For comparison, calculations of transport models plus coalescence afterburner are shown as gold and red bars from JAM model, and blue bars from UrQMD model.

Mass dependence of the mid-rapidity $v_1$ slope, $dv_1/dy$, for $\Lambda$, $^{3}_{\Lambda}$H and $^{4}_{\Lambda}$H from the $\sqrt{s_{NN}}$ = 3 GeV 5-40% mid-central Au+Au collisions. The statistical and systematic uncertainties are presented by vertical lines and square brackets, respectively. The slopes of $p$, $d$, $t$, $^3$He and $^4$He from the same collisions are shown as black circles. The blue and dashed green lines are the results of a linear fit to the measured light nuclei and hypernuclei $v_1$ slopes, respectively. For comparison, calculations of transport models plus coalescence afterburner are shown as gold and red bars from JAM model, and blue bars from UrQMD model.

Mass dependence of the mid-rapidity $v_1$ slope, $dv_1/dy$, for $\Lambda$, $^{3}_{\Lambda}$H and $^{4}_{\Lambda}$H from the $\sqrt{s_{NN}}$ = 3 GeV 5-40% mid-central Au+Au collisions. The statistical and systematic uncertainties are presented by vertical lines and square brackets, respectively. The slopes of $p$, $d$, $t$, $^3$He and $^4$He from the same collisions are shown as black circles. The blue and dashed green lines are the results of a linear fit to the measured light nuclei and hypernuclei $v_1$ slopes, respectively. For comparison, calculations of transport models plus coalescence afterburner are shown as gold and red bars from JAM model, and blue bars from UrQMD model.

Mass dependence of the mid-rapidity $v_1$ slope, $dv_1/dy$, for $\Lambda$, $^{3}_{\Lambda}$H and $^{4}_{\Lambda}$H from the $\sqrt{s_{NN}}$ = 3 GeV 5-40% mid-central Au+Au collisions. The statistical and systematic uncertainties are presented by vertical lines and square brackets, respectively. The slopes of $p$, $d$, $t$, $^3$He and $^4$He from the same collisions are shown as black circles. The blue and dashed green lines are the results of a linear fit to the measured light nuclei and hypernuclei $v_1$ slopes, respectively. For comparison, calculations of transport models plus coalescence afterburner are shown as gold and red bars from JAM model, and blue bars from UrQMD model.

Mass dependence of the mid-rapidity $v_1$ slope, $dv_1/dy$, for $\Lambda$, $^{3}_{\Lambda}$H and $^{4}_{\Lambda}$H from the $\sqrt{s_{NN}}$ = 3 GeV 5-40% mid-central Au+Au collisions. The statistical and systematic uncertainties are presented by vertical lines and square brackets, respectively. The slopes of $p$, $d$, $t$, $^3$He and $^4$He from the same collisions are shown as black circles. The blue and dashed green lines are the results of a linear fit to the measured light nuclei and hypernuclei $v_1$ slopes, respectively. For comparison, calculations of transport models plus coalescence afterburner are shown as gold and red bars from JAM model, and blue bars from UrQMD model.

$v_3\{\Psi_1\}$ vs. centrality for $\pi^+$, $\pi^-$, and protons using the event plane method in $\sqrt{s_{\textrm{NN}}}=3$ GeV Au+Au collisions at STAR.

$v_3\{\Psi_1\}$ vs. centrality for $K^+$, and $K^-$ using the event plane method in $\sqrt{s_{\textrm{NN}}}=3$ GeV Au+Au collisions at STAR.

$v_3\{\Psi_1\}$ vs. centrality for $K^+$, and $K^-$ using the event plane method in $\sqrt{s_{\textrm{NN}}}=3$ GeV Au+Au collisions at STAR.

$v_3\{\Psi_1\}$ vs. rapidity for protons in three large centrality bins from a symmetric acceptance across midrapidity in $\sqrt{s_{\textrm{NN}}}=3$ GeV Au+Au collisions at STAR. Protons exhibit an increasingly negative slope as the centrality increases.

$v_3\{\Psi_1\}$ vs. rapidity for protons in three large centrality bins from a symmetric acceptance across midrapidity in $\sqrt{s_{\textrm{NN}}}=3$ GeV Au+Au collisions at STAR. Protons exhibit an increasingly negative slope as the centrality increases.

$v_3\{\Psi_1\}$ vs. rapidity for protons in three large centrality bins from only the backward region in $\sqrt{s_{\textrm{NN}}}=3$ GeV Au+Au collisions at STAR. Note that the $p_{\mathrm{T}}$ acceptance extends to a lower limit than in Fig. 6.

$v_3\{\Psi_1\}$ vs. rapidity for protons in three large centrality bins from only the backward region in $\sqrt{s_{\textrm{NN}}}=3$ GeV Au+Au collisions at STAR. Note that the $p_{\mathrm{T}}$ acceptance extends to a lower limit than in Fig. 6.

$v_3\{\Psi_1\}$ vs. $p_{\mathrm{T}}$ for protons in three large centrality bins in $\sqrt{s_{\textrm{NN}}}=3$ GeV Au+Au collisions at STAR. $v_3\{\Psi_1\}$ becomes increasingly negative as $p_{\mathrm{T}}$ and centrality increase.

$v_3\{\Psi_1\}$ vs. $p_{\mathrm{T}}$ for protons in three large centrality bins in $\sqrt{s_{\textrm{NN}}}=3$ GeV Au+Au collisions at STAR. $v_3\{\Psi_1\}$ becomes increasingly negative as $p_{\mathrm{T}}$ and centrality increase.

Differential cross section for XI- production as a function of the invariant mass of the XI- with either of the K+ mesons for incident photon energy 3.09 Gev.

Differential cross section for XI- production as a function of the invariant mass of the XI- with either of the K+ mesons for incident photon energy 3.19 Gev.

Differential cross section for XI- production as a function of the invariant mass of the XI- with either of the K+ mesons for incident photon energy 3.29 Gev.

Differential cross section for XI- production as a function of the invariant mass of the XI- with either of the K+ mesons for incident photon energy 3.39 Gev.

Differential cross section for XI- production as a function of the invariant mass of the XI- with either of the K+ mesons for incident photon energy 3.49 Gev.

Differential cross section for XI- production as a function of the invariant mass of the XI- with either of the K+ mesons for incident photon energy 3.59 Gev.

Differential cross section for XI- production as a function of the invariant mass of the XI- with either of the K+ mesons for incident photon energy 3.69 Gev.

Differential cross section for XI- production as a function of the invariant mass of the XI- with either of the K+ mesons for incident photon energy 3.79 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 2.79 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 2.89 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 2.99 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 3.09 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 3.19 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 3.29 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 3.39 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 3.49 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 3.59 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 3.69 Gev.

Differential cross section for XI- production as a function of the invariant mass of the K+ meson pair for incident photon energy 3.79 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 2.79 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 2.89 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 2.99 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 3.09 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 3.19 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 3.29 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 3.39 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 3.49 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 3.59 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 3.69 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of the XI- in the photon-proton cm frame for incident photon energy 3.79 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 2.79 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 2.89 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 2.99 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 3.09 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 3.19 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 3.29 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 3.39 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 3.49 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 3.59 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 3.69 Gev.

Differential cross section for XI- production as a function of the cosine of the polar angle of each K+ in the photon-proton cm frame for incident photon energy 3.79 Gev.

Total cross section fo XI- production.

Differential cross section for XI(1530)- production as a function of the cosine of the polar angle of the XI(1530)- in the photon-proton cm frame for incident photon energy 3.35 to 4.75 GeV.

Total cross section for XI(1530)- production.

Differential cross section for the process GAMMA N --> PI- P for an incident electron energy of 2.561 GeV.

Differential cross section for the process GAMMA N --> PI- P for an incident electron energy of 1.877 GeV.

Differential cross section for the process GAMMA N --> PI- P for an incident electron energy of 1.723 GeV.

Differential cross section for the process GAMMA N --> PI- P for an incident electron energy of 1.173 GeV.

Differential cross section for the process GAMMA P --> PI+ N for an incident electron energy of 5.614 GeV.

Differential cross section for the process GAMMA P --> PI+ N for an incident electron energy of 4.236 GeV.

Differential cross section for the process GAMMA P --> PI+ N for an incident electron energy of 3.400 GeV.

Differential cross section for the process GAMMA P --> PI+ N for an incident electron energy of 2.561 GeV.

Differential cross section for the process GAMMA P --> PI+ N for an incident electron energy of 1.877 GeV.

Differential cross section for the process GAMMA P --> PI+ N for an incident electron energy of 1.723 GeV.

Differential cross section for the process GAMMA P --> PI+ N for an incident electron energy of 1.173 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.1900 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.2100 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.2300 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.2500 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.2700 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.2900 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.3100 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.3300 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.3500 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.3700 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.3900 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.4100 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.4300 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.4500 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.4700 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.4900 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.5100 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.5300 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.5500 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.5700 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.5900 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.6100 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.6300 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.6500 GeV.

A1 and g1/F1 for the P target at incident energy 1.6000 GeV and W = 1.1100 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.1750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.2250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.2750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.3250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.3750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.4250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.4750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.5250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.5750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.6250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.6750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.7250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.7750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.8250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.8750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.9250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.9750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.0250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.0750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.1250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.1750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.2250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.2750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.3250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.3750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.4250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.4750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.5250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.5750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.6250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.6750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.7250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.7750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.8250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.8750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.9250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 2.9750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 3.0250 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 3.0750 GeV.

A1 and g1/F1 for the P target at incident energy 5.7000 GeV and W = 1.1250 GeV.

Results for G1(DEUT)/F1(DEUT) for the deuteron in bins of (W;Q**2), along with average kinematic values and correction factors for each bin. All values are averaged over the event distribution.