$\gamma p \rightarrow J/\psi p$ differential cross sections 10.36–11.44 GeV beam energy range, average $t$ and beam energy in bins of $t$. The first cross section uncertainties are statistical, and the second are systematic. The overall average beam energy is 10.82 GeV. There is an additional fully correlated systematic uncertainty of 19.5% on the total cross section, not included here.

This table contains thinned out samples of the Markov chains used in the parameter estimation of the SDME measurements for $-(t-t_\text{0}) = 0.400\pm0.056~\text{GeV}^2/c^2$, reported in the main article. One in about 250 steps in the chain, which results in 200 different sets of SDMEs, is provided. These values should be used instead of bootstrapping of the results, in order to estimate uncertainties of physics models fitted to this data. To assess how the uncertainties propagate to the model uncertainties, one should evaluate the model under scrutiny for each of the 200 different sets of SDMEs. Plotting all resulting lines in a single plot will create bands which reflect the influence of the uncertainties in the data on the model. This method has the great advantage that all correlations are accurately taken into account.

This table contains thinned out samples of the Markov chains used in the parameter estimation of the SDME measurements for $-(t-t_\text{0}) = 0.597\pm0.057~\text{GeV}^2/c^2$, reported in the main article. One in about 250 steps in the chain, which results in 200 different sets of SDMEs, is provided. These values should be used instead of bootstrapping of the results, in order to estimate uncertainties of physics models fitted to this data. To assess how the uncertainties propagate to the model uncertainties, one should evaluate the model under scrutiny for each of the 200 different sets of SDMEs. Plotting all resulting lines in a single plot will create bands which reflect the influence of the uncertainties in the data on the model. This method has the great advantage that all correlations are accurately taken into account.

This table contains thinned out samples of the Markov chains used in the parameter estimation of the SDME measurements for $-(t-t_\text{0}) = 0.793\pm0.057~\text{GeV}^2/c^2$, reported in the main article. One in about 250 steps in the chain, which results in 200 different sets of SDMEs, is provided. These values should be used instead of bootstrapping of the results, in order to estimate uncertainties of physics models fitted to this data. To assess how the uncertainties propagate to the model uncertainties, one should evaluate the model under scrutiny for each of the 200 different sets of SDMEs. Plotting all resulting lines in a single plot will create bands which reflect the influence of the uncertainties in the data on the model. This method has the great advantage that all correlations are accurately taken into account.

This table contains thinned out samples of the Markov chains used in the parameter estimation of the SDME measurements for $-(t-t_\text{0}) = 0.992\pm0.058~\text{GeV}^2/c^2$, reported in the main article. One in about 250 steps in the chain, which results in 200 different sets of SDMEs, is provided. These values should be used instead of bootstrapping of the results, in order to estimate uncertainties of physics models fitted to this data. To assess how the uncertainties propagate to the model uncertainties, one should evaluate the model under scrutiny for each of the 200 different sets of SDMEs. Plotting all resulting lines in a single plot will create bands which reflect the influence of the uncertainties in the data on the model. This method has the great advantage that all correlations are accurately taken into account.

This table contains thinned out samples of the Markov chains used in the parameter estimation of the SDME measurements for $-(t-t_\text{0}) = 1.189\pm0.058~\text{GeV}^2/c^2$, reported in the main article. One in about 250 steps in the chain, which results in 200 different sets of SDMEs, is provided. These values should be used instead of bootstrapping of the results, in order to estimate uncertainties of physics models fitted to this data. To assess how the uncertainties propagate to the model uncertainties, one should evaluate the model under scrutiny for each of the 200 different sets of SDMEs. Plotting all resulting lines in a single plot will create bands which reflect the influence of the uncertainties in the data on the model. This method has the great advantage that all correlations are accurately taken into account.

This table contains thinned out samples of the Markov chains used in the parameter estimation of the SDME measurements for $-(t-t_\text{0}) = 1.435\pm0.086~\text{GeV}^2/c^2$, reported in the main article. One in about 250 steps in the chain, which results in 200 different sets of SDMEs, is provided. These values should be used instead of bootstrapping of the results, in order to estimate uncertainties of physics models fitted to this data. To assess how the uncertainties propagate to the model uncertainties, one should evaluate the model under scrutiny for each of the 200 different sets of SDMEs. Plotting all resulting lines in a single plot will create bands which reflect the influence of the uncertainties in the data on the model. This method has the great advantage that all correlations are accurately taken into account.

This table contains thinned out samples of the Markov chains used in the parameter estimation of the SDME measurements for $-(t-t_\text{0}) = 1.761\pm0.111~\text{GeV}^2/c^2$, reported in the main article. One in about 250 steps in the chain, which results in 200 different sets of SDMEs, is provided. These values should be used instead of bootstrapping of the results, in order to estimate uncertainties of physics models fitted to this data. To assess how the uncertainties propagate to the model uncertainties, one should evaluate the model under scrutiny for each of the 200 different sets of SDMEs. Plotting all resulting lines in a single plot will create bands which reflect the influence of the uncertainties in the data on the model. This method has the great advantage that all correlations are accurately taken into account.

Photon beam asymmetry Sigma at W= 1.3147 GeV

Photon beam asymmetry Sigma at W= 1.3289 GeV

Photon beam asymmetry Sigma at W= 1.3430 GeV

Photon beam asymmetry Sigma at W= 1.3569 GeV

Photon beam asymmetry Sigma at W= 1.3707 GeV

Photon beam asymmetry Sigma at W= 1.3843 GeV

Photon beam asymmetry Sigma at W= 1.3978 GeV

Photon beam asymmetry Sigma at W= 1.4112 GeV

Photon beam asymmetry Sigma at W= 1.4244 GeV

Excitation function at pion c.m. angle THETA=49 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=57 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=63 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=69 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=75 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at THETA=81 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=87 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=93 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=99 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=104 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=110 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=117 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=123 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=130 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=138 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=148 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Excitation function at pion c.m. angle THETA=162 deg as function of incident photon energy E. The uncertainties are statistical and systematic, combined in quadrature.

Total cross section as a function of incident photon energy E.

Run 3. Total cross section as a function of c.m. energy W.

Excitation function at cos(Theta_eta)= -0.958

Excitation function at cos(Theta_eta)= -0.875

Excitation function at cos(Theta_eta)= -0.792

Excitation function at cos(Theta_eta)= -0.708

Excitation function at cos(Theta_eta)= -0.625

Excitation function at cos(Theta_eta)= -0.542

Excitation function at cos(Theta_eta)= -0.458

Excitation function at cos(Theta_eta)= -0.375

Excitation function at cos(Theta_eta)= -0.292

Excitation function at cos(Theta_eta)= -0.208

Excitation function at cos(Theta_eta)= -0.125

Excitation function at cos(Theta_eta)= -0.042

Excitation function at cos(Theta_eta)= 0.042

Excitation function at cos(Theta_eta)= 0.125

Excitation function at cos(Theta_eta)= 0.208

Excitation function at cos(Theta_eta)= 0.292

Excitation function at cos(Theta_eta)= 0.375

Excitation function at cos(Theta_eta)= 0.458

Excitation function at cos(Theta_eta)= 0.542

Excitation function at cos(Theta_eta)= 0.625

Excitation function at cos(Theta_eta)= 0.708

Excitation function at cos(Theta_eta)= 0.792

Excitation function at cos(Theta_eta)= 0.875

Excitation function at cos(Theta_eta)= 0.958

Excitation function at cos(Theta_eta)= -0.958

Excitation function at cos(Theta_eta)= -0.875

Excitation function at cos(Theta_eta)= -0.792

Excitation function at cos(Theta_eta)= -0.708

Excitation function at cos(Theta_eta)= -0.625

Excitation function at cos(Theta_eta)= -0.542

Excitation function at cos(Theta_eta)= -0.458

Excitation function at cos(Theta_eta)= -0.375

Excitation function at cos(Theta_eta)= -0.292

Excitation function at cos(Theta_eta)= -0.208

Excitation function at cos(Theta_eta)= -0.125

Excitation function at cos(Theta_eta)= -0.042

Excitation function at cos(Theta_eta)= 0.042

Excitation function at cos(Theta_eta)= 0.125

Excitation function at cos(Theta_eta)= 0.208

Excitation function at cos(Theta_eta)= 0.292

Excitation function at cos(Theta_eta)= 0.375

Excitation function at cos(Theta_eta)= 0.458

Excitation function at cos(Theta_eta)= 0.542

Excitation function at cos(Theta_eta)= 0.625

Excitation function at cos(Theta_eta)= 0.708

Excitation function at cos(Theta_eta)= 0.792

Excitation function at cos(Theta_eta)= 0.875

Excitation function at cos(Theta_eta)= 0.958

Differential cross section at c.m. energy 1.8876 GeV

Differential cross section at c.m. energy 1.8933 GeV

Differential cross section at c.m. energy 1.8997 GeV

Differential cross section at c.m. energy 1.9061 GeV

Differential cross section at c.m. energy 1.9125 GeV

Differential cross section at c.m. energy 1.9189 GeV

Differential cross section at c.m. energy 1.9252 GeV

Differential cross section at c.m. energy 1.9315 GeV

Differential cross section at c.m. energy 1.9378 GeV

Differential cross section at c.m. energy 1.9441 GeV

Differential cross section at c.m. energy 1.9504 GeV

Differential cross section at c.m. energy 1.9566 GeV

Differential cross section at c.m. energy 1.8978 GeV

Differential cross section at c.m. energy 1.9011 GeV

Differential cross section at c.m. energy 1.9042 GeV

Differential cross section at c.m. energy 1.9075 GeV

Differential cross section at c.m. energy 1.9123 GeV

Differential cross section at c.m. energy 1.9186 GeV

Differential cross section at c.m. energy 1.9250 GeV

Differential cross section at c.m. energy 1.9313 GeV

Differential cross section at c.m. energy 1.9376 GeV

Differential cross section at c.m. energy 1.9439 GeV

Differential cross section at c.m. energy 1.9501 GeV

Differential cross section at c.m. energy 1.9564 GeV

Target asymmetry T for c.m. energy W= 1.3693 GeV

Target asymmetry T for c.m. energy W= 1.3897 GeV

Target asymmetry T for c.m. energy W= 1.4098 GeV

Target asymmetry T for c.m. energy W= 1.4296 GeV

Target asymmetry T for c.m. energy W= 1.4492 GeV

Target asymmetry T for c.m. energy W= 1.4685 GeV

Target asymmetry T for c.m. energy W= 1.4875 GeV

Target asymmetry T for c.m. energy W= 1.5063 GeV

Target asymmetry T for c.m. energy W= 1.5249 GeV

Target asymmetry T for c.m. energy W= 1.5432 GeV

Target asymmetry T for c.m. energy W= 1.5614 GeV

Target asymmetry T for c.m. energy W= 1.5793 GeV

Target asymmetry T for c.m. energy W= 1.5970 GeV

Target asymmetry T for c.m. energy W= 1.6146 GeV

Target asymmetry T for c.m. energy W= 1.6319 GeV

Target asymmetry T for c.m. energy W= 1.6491 GeV

Target asymmetry T for c.m. energy W= 1.6660 GeV

Target asymmetry T for c.m. energy W= 1.6828 GeV

Target asymmetry T for c.m. energy W= 1.6995 GeV

Target asymmetry T for c.m. energy W= 1.7160 GeV

Target asymmetry T for c.m. energy W= 1.7323 GeV

Target asymmetry T for c.m. energy W= 1.7485 GeV

Target asymmetry T for c.m. energy W= 1.7645 GeV

Target asymmetry T for c.m. energy W= 1.7804 GeV

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

Target asymmetry T for c.m. energy W= 1.8117 GeV

Target asymmetry T for c.m. energy W= 1.8272 GeV

Target asymmetry T for c.m. energy W= 1.8425 GeV

Target asymmetry T for c.m. energy W= 1.8577 GeV

Target asymmetry T for c.m. energy W= 1.8728 GeV

Target asymmetry T for c.m. energy W= 1.8878 GeV

Beam-target asymmetry F for c.m. energy W= 1.3062 GeV

Beam-target asymmetry F for c.m. energy W= 1.3275 GeV

Beam-target asymmetry F for c.m. energy W= 1.3486 GeV

Beam-target asymmetry F for c.m. energy W= 1.3693 GeV

Beam-target asymmetry F for c.m. energy W= 1.3897 GeV

Beam-target asymmetry F for c.m. energy W= 1.4098 GeV

Beam-target asymmetry F for c.m. energy W= 1.4296 GeV

Beam-target asymmetry F for c.m. energy W= 1.4492 GeV

Beam-target asymmetry F for c.m. energy W= 1.4685 GeV

Beam-target asymmetry F for c.m. energy W= 1.4875 GeV

Beam-target asymmetry F for c.m. energy W= 1.5063 GeV

Beam-target asymmetry F for c.m. energy W= 1.5249 GeV

Beam-target asymmetry F for c.m. energy W= 1.5432 GeV

Beam-target asymmetry F for c.m. energy W= 1.5614 GeV

Beam-target asymmetry F for c.m. energy W= 1.5793 GeV

Beam-target asymmetry F for c.m. energy W= 1.5970 GeV

Beam-target asymmetry F for c.m. energy W= 1.6146 GeV

Beam-target asymmetry F for c.m. energy W= 1.6319 GeV

Beam-target asymmetry F for c.m. energy W= 1.6491 GeV

Beam-target asymmetry F for c.m. energy W= 1.6660 GeV

Beam-target asymmetry F for c.m. energy W= 1.6828 GeV

Beam-target asymmetry F for c.m. energy W= 1.6995 GeV

Beam-target asymmetry F for c.m. energy W= 1.7160 GeV

Beam-target asymmetry F for c.m. energy W= 1.7323 GeV

Beam-target asymmetry F for c.m. energy W= 1.7485 GeV

Beam-target asymmetry F for c.m. energy W= 1.7645 GeV

Beam-target asymmetry F for c.m. energy W= 1.7804 GeV

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

Beam-target asymmetry F for c.m. energy W= 1.8117 GeV

Beam-target asymmetry F for c.m. energy W= 1.8272 GeV

Beam-target asymmetry F for c.m. energy W= 1.8425 GeV

Beam-target asymmetry F for c.m. energy W= 1.8577 GeV

Beam-target asymmetry F for c.m. energy W= 1.8728 GeV

Beam-target asymmetry F for c.m. energy W= 1.8878 GeV

No description provided.

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Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^+)}{\mathrm{d} p_T(D^+)}$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^+)<4.5$, $p_T(D^+)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^0)}{\mathrm{d} y(\Upsilon(1S))}$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^0)<4.5$, $p_T(D^0)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^+)}{\mathrm{d} y(\Upsilon(1S))}$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^+)<4.5$, $p_T(D^+)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^0)}{\mathrm{d} y(D^0)}$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^0)<4.5$, $p_T(D^0)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^+)}{\mathrm{d} y(D^+)}$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^+)<4.5$, $p_T(D^+)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{\pi}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^0)}{\mathrm{d} \left| \Delta \phi \right| }$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^0)<4.5$, $p_T(D^0)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{\pi}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^+)}{\mathrm{d} \left| \Delta \phi \right| }$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^+)<4.5$, $p_T(D^+)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^0)}{\mathrm{d} \left| \Delta y \right| }$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^0)<4.5$, $p_T(D^0)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^+)}{\mathrm{d} \left| \Delta y \right| }$ for $2<y(\Upsilon(1S))<4.5$, for $2<y(D^+)<4.5$, $p_T(D^+)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^0)}{\mathrm{d} p_T(\Upsilon(1S)D^0) }$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^0)<4.5$, $p_T(D^0)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^+)}{\mathrm{d} p_T(\Upsilon(1S)D^+)}$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^+)<4.5$, $p_T(D^+)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^0)}{\mathrm{d} y(\Upsilon(1S)D^0) }$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^0)<4.5$, $p_T(D^0)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^+)}{\mathrm{d} y(\Upsilon(1S)D^+)}$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^+)<4.5$, $p_T(D^+)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^0)}{\mathrm{d} \mathcal{A}_T }$, where $\mathcal{A}_T = \frac{p_T(\Upsilon(1S))-p_T(D^0)}{p_T(\Upsilon(1S))-p_T(D^0)}$, for $2<y(\Upsilon(1S))<4.5$, $2<y(D^0)<4.5$, $p_T(D^0)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^+)}{\mathrm{d} \mathcal{A}_T }$, where $\mathcal{A}_T = \frac{p_T(\Upsilon(1S))-p_T(D^0)}{p_T(\Upsilon(1S))-p_T(D^0)}$, for $2<y(\Upsilon(1S))<4.5$, $2<y(D^+)<4.5$, $p_T(D^+)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^0)}{\mathrm{d} m(\Upsilon(1S)D^0) }$, for $2<y(\Upsilon(1S))<4.5$, $2<y(D^0)<4.5$, $p_T(D^0)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Normalized differential cross-section $\frac{1}{\sigma}\frac{ \mathrm{d}\sigma(\Upsilon(1S)D^+)}{\mathrm{d} m(\Upsilon(1S)D^+)}$ for $2<y(\Upsilon(1S))<4.5$, $2<y(D^+)<4.5$, $p_T(D^+)>1$ GeV/$c$. Only statistical uncertainties are quoted as systematic uncertainties are found to be negligible. The distribution is normalized to unity.

Target asymmetry T for c.m. cos(Theta_pi0)= 0.819

Target asymmetry T for c.m. cos(Theta_pi0)= 0.707

Target asymmetry T for c.m. cos(Theta_pi0)= 0.574

Target asymmetry T for c.m. cos(Theta_pi0)= 0.423

Target asymmetry T for c.m. cos(Theta_pi0)= 0.259

Target asymmetry T for c.m. cos(Theta_pi0)= 0.087

Target asymmetry T for c.m. cos(Theta_pi0)= -0.087

Target asymmetry T for c.m. cos(Theta_pi0)= -0.259

Target asymmetry T for c.m. cos(Theta_pi0)= -0.423

Target asymmetry T for c.m. cos(Theta_pi0)= -0.574

Target asymmetry T for c.m. cos(Theta_pi0)= -0.707

Target asymmetry T for c.m. cos(Theta_pi0)= -0.819

Target asymmetry T for c.m. cos(Theta_pi0)= -0.906

Target asymmetry T for c.m. cos(Theta_pi0)= -0.966

Target asymmetry T for c.m. cos(Theta_pi0)= -0.996

Axis error includes +- 0.0/0.0 contribution (?////).

Double differential cross-section for $J/\psi$-from-$b$ mesons as a function of $p_\perp$ in bins of $y$. The first uncertainties are statistical, the second are the correlated systematic uncertainties shared between bins and the last are the uncorrelated systematic uncertainties.

The fraction of $J/\psi$-from-$b$ mesons (in %) in bins of the $J/\psi$ $p_\perp$ and $y$. The uncertainties are statistical only. The systematic uncertainties are negligible.

The fraction of $J/\psi$-from-$b$ mesons (in %) in bins of the $J/\psi$ $p_\perp$ and $y$. The uncertainties are statistical only. The systematic uncertainties are negligible.

Differential cross-sections as a function of $p_\perp$ integrated over $y$ for prompt $J/\psi$ mesons. The first uncertainties are statistical and the second (third) are uncorrelated (correlated) systematic uncertainties amongst bins.

Differential cross-sections as a function of $p_\perp$ integrated over $y$ for prompt $J/\psi$ mesons. The first uncertainties are statistical and the second (third) are uncorrelated (correlated) systematic uncertainties amongst bins.

Differential cross-sections as a function of $p_\perp$ integrated over $y$ for $J/\psi$-from-$b$ mesons. The first uncertainties are statistical and the second (third) are uncorrelated (correlated) systematic uncertainties amongst bins.

Differential cross-sections as a function of $p_\perp$ integrated over $y$ for $J/\psi$-from-$b$ mesons. The first uncertainties are statistical and the second (third) are uncorrelated (correlated) systematic uncertainties amongst bins.

Differential cross-sections as a function of $y$ integrated over $p_\perp$ for prompt $J/\psi$ mesons. The first uncertainties are statistical and the second (third) are the correlated (uncorrelated) systematic uncertainties.

Differential cross-sections as a function of $y$ integrated over $p_\perp$ for prompt $J/\psi$ mesons. The first uncertainties are statistical and the second (third) are the correlated (uncorrelated) systematic uncertainties.

Differential cross-sections as a function of $y$ integrated over $p_\perp$ for $J/\psi$-from-$b$ mesons. The first uncertainties are statistical and the second (third) are the correlated (uncorrelated) systematic uncertainties.

Differential cross-sections as a function of $y$ integrated over $p_\perp$ for $J/\psi$-from-$b$ mesons. The first uncertainties are statistical and the second (third) are the correlated (uncorrelated) systematic uncertainties.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $p_\perp$ in bins of $y$ for prompt $J/\psi$ mesons. The systematic errors are negligible.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $p_\perp$ in bins of $y$ for prompt $J/\psi$ mesons. The systematic errors are negligible.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $p_\perp$ in bins of $y$ for $J/\psi$-from-$b$ mesons. The systematic errors are negligible.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $p_\perp$ in bins of $y$ for $J/\psi$-from-$b$ mesons. The systematic errors are negligible.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $y$ integrated over $p_\perp$ for prompt $J/\psi$ mesons. The systematic errors are negligible.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $y$ integrated over $p_\perp$ for prompt $J/\psi$ mesons. The systematic errors are negligible.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $y$ integrated over $p_\perp$ for $J/\psi$-from-$b$ mesons. The systematic errors are negligible.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $y$ integrated over $p_\perp$ for $J/\psi$-from-$b$ mesons. The systematic errors are negligible.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $p_\perp$ integrated over $y$ for prompt $J/\psi$ mesons.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $p_\perp$ integrated over $y$ for prompt $J/\psi$ mesons.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $p_\perp$ integrated over $y$ for $J/\psi$-from-$b$ mesons. The systematic errors are negligible.

Ratios of differential cross-sections between measurements at $\sqrt{s} = 13$ TeV and $\sqrt{s} = 8$ TeV as a function of $p_\perp$ integrated over $y$ for $J/\psi$-from-$b$ mesons. The systematic errors are negligible.

Excitation function at cos(Theta_eta)= -0.833

Excitation function at cos(Theta_eta)= -0.767

Excitation function at cos(Theta_eta)= -0.700

Excitation function at cos(Theta_eta)= -0.633

Excitation function at cos(Theta_eta)= -0.567

Excitation function at cos(Theta_eta)= -0.500

Excitation function at cos(Theta_eta)= -0.433

Excitation function at cos(Theta_eta)= -0.367

Excitation function at cos(Theta_eta)= -0.300

Excitation function at cos(Theta_eta)= -0.233

Excitation function at cos(Theta_eta)= -0.167

Excitation function at cos(Theta_eta)= -0.100

Excitation function at cos(Theta_eta)= -0.033

Excitation function at cos(Theta_eta)= 0.033

Excitation function at cos(Theta_eta)= 0.100

Excitation function at cos(Theta_eta)= 0.167

Excitation function at cos(Theta_eta)= 0.233

Excitation function at cos(Theta_eta)= 0.300

Excitation function at cos(Theta_eta)= 0.367

Excitation function at cos(Theta_eta)= 0.433

Excitation function at cos(Theta_eta)= 0.500

Excitation function at cos(Theta_eta)= 0.567

Excitation function at cos(Theta_eta)= 0.633

Excitation function at cos(Theta_eta)= 0.700

Excitation function at cos(Theta_eta)= 0.767

Excitation function at cos(Theta_eta)= 0.833

Excitation function at cos(Theta_eta)= 0.900

Excitation function at cos(Theta_eta)= 0.967

Excitation function at cos(Theta_eta)= -0.833

Excitation function at cos(Theta_eta)= -0.767

Excitation function at cos(Theta_eta)= -0.700

Excitation function at cos(Theta_eta)= -0.633

Excitation function at cos(Theta_eta)= -0.567

Excitation function at cos(Theta_eta)= -0.500

Excitation function at cos(Theta_eta)= -0.433

Excitation function at cos(Theta_eta)= -0.367

Excitation function at cos(Theta_eta)= -0.300

Excitation function at cos(Theta_eta)= -0.233

Excitation function at cos(Theta_eta)= -0.167

Excitation function at cos(Theta_eta)= -0.100

Excitation function at cos(Theta_eta)= -0.033

Excitation function at cos(Theta_eta)= 0.033

Excitation function at cos(Theta_eta)= 0.100

Excitation function at cos(Theta_eta)= 0.167

Excitation function at cos(Theta_eta)= 0.233

Excitation function at cos(Theta_eta)= 0.300

Excitation function at cos(Theta_eta)= 0.367

Excitation function at cos(Theta_eta)= 0.433

Excitation function at cos(Theta_eta)= 0.500

Excitation function at cos(Theta_eta)= 0.567

Excitation function at cos(Theta_eta)= 0.633

Excitation function at cos(Theta_eta)= 0.700

Excitation function at cos(Theta_eta)= 0.767

Excitation function at cos(Theta_eta)= 0.833

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.200-1.250 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.250-1.300 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.300-1.350 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.350-1.400 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.400-1.450 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.450-1.500 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.500-1.550 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.550-1.600 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.600-1.650 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.650-1.700 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.700-1.800 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.800-1.900 GeV.

Differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.900-2.000 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.125-1.150 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.150-1.175 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.175-1.20 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.200-1.250 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.250-1.300 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.300-1.350 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.350-1.400 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.400-1.450 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.450-1.500 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.500-1.550 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.550-1.600 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.600-1.650 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.650-1.700 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.700-1.800 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.800-1.900 GeV.

Inclusive differential cross-sections of $\omega$ mesons produced off the free proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.900-2.000 GeV.

Total cross-section as a function of the incident photon energy for $\omega$ mesons produced off the free proton obtained from exclusive and inclusive analysis$.

Slope parameter and horizontal level from the fits to the differential cross-sections $d\sigma/dt$ for $\omega$ mesons produced off the free proton.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.158-1.208 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.208-1.233 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.233-1.258 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.258-1.308 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.308-1.358 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.358-1.408 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.408-1.508 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.508-1.608 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.608-1.708 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.708-1.808 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.808-1.908 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound proton versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.908-2.008 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.158-1.208 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.208-1.233 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.233-1.258 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.258-1.308 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.308-1.358 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.358-1.408 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.408-1.508 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.508-1.608 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.608-1.708 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.708-1.808 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.808-1.908 GeV.

Differential cross-sections of $\omega$ mesons produced off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.908-2.008 GeV.

Slope parameter and horizontal level from the fits to the differential cross-sections $d\sigma/dt$ for $\omega$ mesons produced off the bound proton.

Slope parameter and horizontal level from the fits to the differential cross-sections $d\sigma/dt$ for $\omega$ mesons produced off the bound neutron.

Inclusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.158-1.208 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.208-1.233 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.233-1.258 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.258-1.308 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.308-1.358 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.358-1.408 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.408-1.508 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.508-1.608 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.608-1.708 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.708-1.808 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.808-1.908 GeV.

Inlusive differential cross-sections of $\omega$ mesons produced off deuterium versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.908-2.008 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.158-1.208 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.208-1.233 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.233-1.258 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.258-1.308 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.308-1.358 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.358-1.408 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.408-1.508 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.508-1.608 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.608-1.708 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.708-1.808 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.808-1.908 GeV.

Sum of the exclusive differential cross-sections of $\omega$ mesons produced off the bound proton and off the bound neutron versus $\cos(\theta^\omega_{\mathrm{c.m.}})$ and versus the momentum transfer to the nucleon, $t$, for incident photon energy $E_\gamma$ = 1.908-2.008 GeV.

Total cross-section as a function of the incident photon energy for $\omega$ mesons produced off the bound proton $\sigma_p^{\mathrm{bound}}$, off the bound neutron $\sigma_n^{\mathrm{bound}}$, the sum of the two exclusive cross-sections $\sigma_p^{\mathrm{bound}}+\sigma_n^{\mathrm{bound}}$, the quasi-free inclusive cross-section $\sigma_{\mathrm{incl}}$ and the cross-section off the neutron calculated by $\sigma_{\mathrm{incl}}-\sigma_p^{\mathrm{bound}}$.

Differential cross-section for $\eta_c(1S)$ from inclusive charmonium production in b-hadrons decays for $p_T > 6.5$ [GeV/$c$] and $2.0 < y < 4.5$. The reported uncertainties are total errors.

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

Et EMC distributions for sqrt(sNN) = 62.4 GeV Au+Au collisions shown in 5% wide centrality bins.

Et EMC distributions for sqrt(sNN) = 62.4 GeV Au+Au collisions shown in 5% wide centrality bins.

Et EMC distributions for sqrt(sNN) = 62.4 GeV Au+Au collisions shown in 5% wide centrality bins.

Et EMC distributions for sqrt(sNN) = 62.4 GeV Au+Au collisions shown in 5% wide centrality bins.

Et EMC distributions for sqrt(sNN) = 62.4 GeV Au+Au collisions shown in 5% wide centrality bins.

Et EMC distributions for sqrt(sNN) = 62.4 GeV Au+Au collisions shown in 5% wide centrality bins.

Et EMC distributions for sqrt(sNN) = 62.4 GeV Au+Au collisions shown in 5% wide centrality bins.

Et EMC distributions for sqrt(sNN) = 62.4 GeV Au+Au collisions shown in 5% wide centrality bins.

Et EMC distributions for sqrt(sNN) = 62.4 GeV Au+Au collisions shown in 5% wide centrality bins.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in Au+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in p+p collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in d+Au collisions.

The number of quark participants as a function of the number of nucleon participants.

The number of quark participants as a function of the number of nucleon participants.

The number of quark participants as a function of the number of nucleon participants.

The ratio of the number of quark participants to the number of nucleon participants as a function of the number of nucleon participants.

The ratio of the number of quark participants to the number of nucleon participants as a function of the number of nucleon participants.

The ratio of the number of quark participants to the number of nucleon participants as a function of the number of nucleon participants.

dE_T/deta normalized by the number of participant pairs as a function of the number of participants.

dE_T/deta normalized by the number of participant pairs as a function of the number of participants.

dE_T/deta normalized by the number of participant pairs as a function of the number of participants.

dE_T/deta normalized by the number of participant quark pairs as a function of the number of nucleon participants.

dE_T/deta normalized by the number of participant quark pairs as a function of the number of nucleon participants.

dE_T/deta normalized by the number of participant quark pairs as a function of the number of nucleon participants.

dE_T/deta as a function of the number of quark participants.

dE_T/deta as a function of the number of quark participants.

dE_T/deta as a function of the number of quark participants.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in p+p collisions.

Distribution of the number of quark participants in 200 GeV Au+Au collsions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in p+p collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in Au+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in d+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in d+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in Au+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in d+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in Au+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in Au+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in d+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in Au+Au collisions.

Corrected dE_T/deta distributions at sqrt(sNN) = 200 GeV for five sectors of PbSc in p+p collisions.

Differential cross-section for $Z$+jet in the leading jet pseudorapidity, $\eta^{\mathrm{jet}}$.

Differential cross-section for $Z$+jet in the boson $Z$ rapidity, $y^Z$.

Cross-section for $Z$+jet production, differential in the $Z$ boson transverse momentum, $p_{T}^{Z}$.

Cross-section for $Z$+jet production, differential in the difference in $\phi$ between the $Z$ boson and the leading jet, $\Delta \phi$.

Cross-section for $Z$+jet production, differential in the difference in rapidity between the $Z$ boson and the leading jet, $\Delta y$.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 0.925 to 0.950 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 0.950 to 0.975 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 0.975 to 1.000 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.000 to 1.025 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.025 to 1.050 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.050 to 1.075 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.100 to 1.125 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.125 to 1.150 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.150 to 1.175 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.175 to 1.200 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.200 to 1.225 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.225 to 1.250 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.250 to 1.275 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.275 to 1.300 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.300 to 1.350 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.350 to 1.400 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.400 to 1.450 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.450 to 1.500 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.500 to 1.550 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.550 to 1.600 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.600 to 1.650 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.650 to 1.700 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.700 to 1.750 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.750 to 1.800 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.800 to 1.850 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.850 to 1.900 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.900 to 1.950 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 1.950 to 2.000 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.000 to 2.050 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.050 to 2.100 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.100 to 2.150 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.150 to 2.200 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.200 to 2.250 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.250 to 2.300 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.300 to 2.350 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.350 to 2.400 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.400 to 2.450 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the cosine of the centre-of-mass scattering angle of the PI0 for photon energies from 2.450 to 2.500 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 0.850 to 0.875 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 0.875 to 0.900 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 0.900 to 0.925 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 0.925 to 0.950 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 0.950 to 0.975 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 0.975 to 1.000 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.000 to 1.025 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.025 to 1.050 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.050 to 1.075 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.100 to 1.125 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.125 to 1.150 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.150 to 1.175 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.175 to 1.200 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.200 to 1.225 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.225 to 1.250 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.250 to 1.275 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.275 to 1.300 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.300 to 1.350 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.350 to 1.400 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.400 to 1.450 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.450 to 1.500 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.500 to 1.550 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.550 to 1.600 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.600 to 1.650 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.650 to 1.700 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.700 to 1.750 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.750 to 1.800 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.800 to 1.850 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.850 to 1.900 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.900 to 1.950 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 1.950 to 2.000 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.000 to 2.050 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.050 to 2.100 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.100 to 2.150 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.150 to 2.200 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.200 to 2.250 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.250 to 2.300 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.300 to 2.350 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.350 to 2.400 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.400 to 2.450 GeV.

Differential cross section for the process GAMMA P --> PI0 P as a function of the scattering angle of the PI0 for photon energies from 2.450 to 2.500 GeV.

Photon beam asymmetry at incident photon energy 1.031 GeV.

Photon beam asymmetry at incident photon energy 1.064 GeV.

Photon beam asymmetry at incident photon energy 1.097 GeV.

Photon beam asymmetry at incident photon energy 1.130 GeV.

Photon beam asymmetry at incident photon energy 1.163 GeV.

Photon beam asymmetry at incident photon energy 1.196 GeV.

Photon beam asymmetry at incident photon energy 1.229 GeV.

Photon beam asymmetry at incident photon energy 1.262 GeV.

Photon beam asymmetry at incident photon energy 1.295 GeV.

Photon beam asymmetry at incident photon energy 1.328 GeV.

Photon beam asymmetry at incident photon energy 1.361 GeV.

Photon beam asymmetry at incident photon energy 1.394 GeV.

Photon beam asymmetry at incident photon energy 1.427 GeV.

Photon beam asymmetry at incident photon energy 1.460 GeV.

Photon beam asymmetry at incident photon energy 1.493 GeV.

Photon beam asymmetry at incident photon energy 1.526 GeV.

Photon beam asymmetry at incident photon energy 1.559 GeV.

Photon beam asymmetry at incident photon energy 1.592 GeV.

Photon beam asymmetry at incident photon energy 1.625 GeV.

Photon beam asymmetry at incident photon energy 1.658 GeV.

Differential cross section for ETA production at incident photon energy 1.000 to 1.050 GeV.

Differential cross section for ETA production at incident photon energy 1.050 to 1.100 GeV.

Differential cross section for ETA production at incident photon energy 1.100 to 1.150 GeV.

Differential cross section for ETA production at incident photon energy 1.150 to 1.200 GeV.

Differential cross section for ETA production at incident photon energy 1.200 to 1.250 GeV.

Differential cross section for ETA production at incident photon energy 1.250 to 1.300 GeV.

Differential cross section for ETA production at incident photon energy 1.300 to 1.350 GeV.

Differential cross section for ETA production at incident photon energy 1.350 to 1.400 GeV.

Differential cross section for ETA production at incident photon energy 1.400 to 1.450 GeV.

Differential cross section for ETA production at incident photon energy 1.450 to 1.500 GeV.

Differential cross section for ETA production at incident photon energy 1.500 to 1.550 GeV.

Differential cross section for ETA production at incident photon energy 1.550 to 1.600 GeV.

Differential cross section for ETA production at incident photon energy 1.600 to 1.650 GeV.

Differential cross section for ETA production at incident photon energy 1.650 to 1.700 GeV.

Differential cross section for ETA production at incident photon energy 1.700 to 1.750 GeV.

Differential cross section for ETA production at incident photon energy 1.750 to 1.800 GeV.

Differential cross section for ETA production at incident photon energy 1.800 to 1.850 GeV.

Differential cross section for ETA production at incident photon energy 1.850 to 1.900 GeV.

Differential cross section for ETA production at incident photon energy 1.900 to 1.950 GeV.

Differential cross section for ETA production at incident photon energy 1.950 to 2.000 GeV.

Differential cross section for ETA production at incident photon energy 2.000 to 2.050 GeV.

Differential cross section for ETA production at incident photon energy 2.050 to 2.100 GeV.

Differential cross section for ETA production at incident photon energy 2.100 to 2.150 GeV.

Differential cross section for ETA production at incident photon energy 2.150 to 2.200 GeV.

Differential cross section for ETA production at incident photon energy 2.200 to 2.250 GeV.

Differential cross section for ETA production at incident photon energy 2.250 to 2.300 GeV.

Differential cross section for ETA production at incident photon energy 2.300 to 2.350 GeV.

Differential cross section for ETA production at incident photon energy 2.350 to 2.400 GeV.

Differential cross section for ETA production at incident photon energy 2.400 to 2.450 GeV.

Differential cross section for ETA production at incident photon energy 2.450 to 2.500 GeV.

Differential cross section for ETA production at incident photon energy 2.500 to 2.550 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.500 to 1.550 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.550 to 1.600 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.600 to 1.650 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.650 to 1.700 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.700 to 1.750 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.750 to 1.800 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.800 to 1.850 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.850 to 1.900 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.900 to 1.950 GeV.

Differential cross section for ETAPRIME production at incident photon energy 1.950 to 2.000 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.000 to 2.050 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.050 to 2.100 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.100 to 2.150 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.150 to 2.200 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.200 to 2.250 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.250 to 2.300 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.300 to 2.350 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.350 to 2.400 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.400 to 2.450 GeV.

Differential cross section for ETAPRIME production at incident photon energy 2.450 to 2.500 GeV.

Total P GAMMA --> ETA P cross section.

Total P GAMMA --> ETAPRIME P cross section.

Differential cross sections at Q**2=6.564 GeV**2, EPSILON=0.4523, W=1.112 GeV and COS(THETA(*))=-0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.564 GeV**2, EPSILON=0.4523, W=1.112 GeV and COS(THETA(*))=-0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.564 GeV**2, EPSILON=0.4523, W=1.112 GeV and COS(THETA(*))=0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.564 GeV**2, EPSILON=0.4523, W=1.112 GeV and COS(THETA(*))=0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.564 GeV**2, EPSILON=0.4523, W=1.112 GeV and COS(THETA(*))=0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.564 GeV**2, EPSILON=0.4523, W=1.112 GeV and COS(THETA(*))=0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.564 GeV**2, EPSILON=0.4523, W=1.112 GeV and COS(THETA(*))=0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=-0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=-0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=-0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=-0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=-0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.5 GeV**2, EPSILON=0.45, W=1.152 GeV and COS(THETA(*))=0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=-0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=-0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=-0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=-0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=-0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.432 GeV**2, EPSILON=0.4478, W=1.192 GeV and COS(THETA(*))=0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=-0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=-0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=-0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=-0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=-0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.36 GeV**2, EPSILON=0.4458, W=1.232 GeV and COS(THETA(*))=0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=-0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=-0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=-0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=-0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=-0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.288 GeV**2, EPSILON=0.4434, W=1.272 GeV and COS(THETA(*))=0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=-0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=-0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=-0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=-0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=-0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.212 GeV**2, EPSILON=0.4411, W=1.312 GeV and COS(THETA(*))=0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=-0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=-0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=-0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=-0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=-0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.136 GeV**2, EPSILON=0.4383, W=1.352 GeV and COS(THETA(*))=0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=-0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=-0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=-0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=-0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=-0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=0.1 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=0.3 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=0.5 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=0.7 for the small SOS spectrometer.

Differential cross sections at Q**2=6.06 GeV**2, EPSILON=0.4351, W=1.392 GeV and COS(THETA(*))=0.9 for the small SOS spectrometer.

Differential cross sections at Q**2=7.924 GeV**2, EPSILON=0.226, W=1.112 GeV and COS(THETA(*))=-0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.924 GeV**2, EPSILON=0.226, W=1.112 GeV and COS(THETA(*))=-0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.924 GeV**2, EPSILON=0.226, W=1.112 GeV and COS(THETA(*))=-0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.924 GeV**2, EPSILON=0.226, W=1.112 GeV and COS(THETA(*))=0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.924 GeV**2, EPSILON=0.226, W=1.112 GeV and COS(THETA(*))=0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.924 GeV**2, EPSILON=0.226, W=1.112 GeV and COS(THETA(*))=0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.848 GeV**2, EPSILON=0.2251, W=1.152 GeV and COS(THETA(*))=-0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.848 GeV**2, EPSILON=0.2251, W=1.152 GeV and COS(THETA(*))=-0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.848 GeV**2, EPSILON=0.2251, W=1.152 GeV and COS(THETA(*))=-0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.848 GeV**2, EPSILON=0.2251, W=1.152 GeV and COS(THETA(*))=0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.848 GeV**2, EPSILON=0.2251, W=1.152 GeV and COS(THETA(*))=0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.848 GeV**2, EPSILON=0.2251, W=1.152 GeV and COS(THETA(*))=0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.772 GeV**2, EPSILON=0.2236, W=1.192 GeV and COS(THETA(*))=-0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.772 GeV**2, EPSILON=0.2236, W=1.192 GeV and COS(THETA(*))=-0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.772 GeV**2, EPSILON=0.2236, W=1.192 GeV and COS(THETA(*))=-0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.772 GeV**2, EPSILON=0.2236, W=1.192 GeV and COS(THETA(*))=0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.772 GeV**2, EPSILON=0.2236, W=1.192 GeV and COS(THETA(*))=0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.772 GeV**2, EPSILON=0.2236, W=1.192 GeV and COS(THETA(*))=0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.692 GeV**2, EPSILON=0.2222, W=1.232 GeV and COS(THETA(*))=-0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.692 GeV**2, EPSILON=0.2222, W=1.232 GeV and COS(THETA(*))=-0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.692 GeV**2, EPSILON=0.2222, W=1.232 GeV and COS(THETA(*))=-0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.692 GeV**2, EPSILON=0.2222, W=1.232 GeV and COS(THETA(*))=0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.692 GeV**2, EPSILON=0.2222, W=1.232 GeV and COS(THETA(*))=0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.692 GeV**2, EPSILON=0.2222, W=1.232 GeV and COS(THETA(*))=0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.608 GeV**2, EPSILON=0.2211, W=1.272 GeV and COS(THETA(*))=-0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.608 GeV**2, EPSILON=0.2211, W=1.272 GeV and COS(THETA(*))=-0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.608 GeV**2, EPSILON=0.2211, W=1.272 GeV and COS(THETA(*))=-0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.608 GeV**2, EPSILON=0.2211, W=1.272 GeV and COS(THETA(*))=0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.608 GeV**2, EPSILON=0.2211, W=1.272 GeV and COS(THETA(*))=0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.608 GeV**2, EPSILON=0.2211, W=1.272 GeV and COS(THETA(*))=0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.524 GeV**2, EPSILON=0.2195, W=1.312 GeV and COS(THETA(*))=-0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.524 GeV**2, EPSILON=0.2195, W=1.312 GeV and COS(THETA(*))=-0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.524 GeV**2, EPSILON=0.2195, W=1.312 GeV and COS(THETA(*))=-0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.524 GeV**2, EPSILON=0.2195, W=1.312 GeV and COS(THETA(*))=0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.524 GeV**2, EPSILON=0.2195, W=1.312 GeV and COS(THETA(*))=0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.524 GeV**2, EPSILON=0.2195, W=1.312 GeV and COS(THETA(*))=0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.436 GeV**2, EPSILON=0.218, W=1.352 GeV and COS(THETA(*))=-0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.436 GeV**2, EPSILON=0.218, W=1.352 GeV and COS(THETA(*))=-0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.436 GeV**2, EPSILON=0.218, W=1.352 GeV and COS(THETA(*))=-0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.436 GeV**2, EPSILON=0.218, W=1.352 GeV and COS(THETA(*))=0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.436 GeV**2, EPSILON=0.218, W=1.352 GeV and COS(THETA(*))=0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.348 GeV**2, EPSILON=0.2161, W=1.392 GeV and COS(THETA(*))=-0.83 for the large SOS spectrometer.

Differential cross sections at Q**2=7.348 GeV**2, EPSILON=0.2161, W=1.392 GeV and COS(THETA(*))=-0.5 for the large SOS spectrometer.

Differential cross sections at Q**2=7.348 GeV**2, EPSILON=0.2161, W=1.392 GeV and COS(THETA(*))=-0.17 for the large SOS spectrometer.

Differential cross sections at Q**2=7.348 GeV**2, EPSILON=0.2161, W=1.392 GeV and COS(THETA(*))=0.17 for the large SOS spectrometer.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Beam asymmetry as a function of the PI0 centre of mass scattering angle.

Inclusive energy distribution for incident photon energy 1.550 to 2.200 GeV.

Inclusive angular distribution for C12.

Inclusive angular distribution for CA40.

Inclusive angular distribution for NB93.

Inclusive angular distribution for PB.

Exclusive single ETA production cross section.

Inclusive single ETA production cross section.

Measured angular distribution for an incident photon energy of 0.750 GeV.

Measured angular distribution for an incident photon energy of 0.800 GeV.

Measured angular distribution for an incident photon energy of 0.850 GeV.

Measured angular distribution for an incident photon energy of 0.900 GeV.

Measured angular distribution for an incident photon energy of 0.950 GeV.

Measured angular distribution for an incident photon energy of 1.000 GeV.

Measured angular distribution for an incident photon energy of 1.100 GeV.

Measured angular distribution for an incident photon energy of 1.200 GeV.

Measured angular distribution for an incident photon energy of 1.300 GeV.

Measured angular distribution for an incident photon energy of 1.400 GeV.

Measured angular distribution for an incident photon energy of 1.500 GeV.

Measured angular distribution for an incident photon energy of 1.600 GeV.

Measured angular distribution for an incident photon energy of 1.700 GeV.

Measured angular distribution for an incident photon energy of 1.800 GeV.

Measured angular distribution for an incident photon energy of 1.900 GeV.

Measured angular distribution for an incident photon energy of 2.000 GeV.

Measured angular distribution for an incident photon energy of 2.100 GeV.

Measured angular distribution for an incident photon energy of 2.200 GeV.

Measured angular distribution for an incident photon energy of 2.400 GeV.

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.