Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 1.332 GeV and W = 1.839 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 1.433 GeV and W = 1.889 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 1.534 GeV and W = 1.939 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 1.635 GeV and W = 1.987 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 1.737 GeV and W = 2.035 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 1.838 GeV and W = 2.081 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 1.939 GeV and W = 2.126 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 2.039 GeV and W = 2.170 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 2.139 GeV and W = 2.212 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 2.240 GeV and W = 2.255 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 2.341 GeV and W = 2.296 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 2.443 GeV and W = 2.338 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 2.543 GeV and W = 2.377 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 2.642 GeV and W = 2.416 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ LAMBDA for incident energy = 2.741 GeV and W = 2.454 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 1.232 GeV and W = 1.787 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 1.332 GeV and W = 1.839 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 1.433 GeV and W = 1.889 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 1.534 GeV and W = 1.939 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 1.635 GeV and W = 1.987 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 1.737 GeV and W = 2.035 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 1.838 GeV and W = 2.081 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 1.939 GeV and W = 2.126 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 2.039 GeV and W = 2.170 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 2.139 GeV and W = 2.212 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 2.240 GeV and W = 2.255 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 2.341 GeV and W = 2.296 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 2.443 GeV and W = 2.338 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 2.543 GeV and W = 2.377 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 2.642 GeV and W = 2.416 GeV.

Coefficients Cx and Cz for the reaction GAMMA P --> K+ SIGMA0 for incident energy = 2.741 GeV and W = 2.454 GeV.

Example of $\Lambda$ signal for 0-40% most central events, over mixed-event background for the bin $-0.05 < y_{cm} < 0.05$ and reduced transverse masses between $100-150 MeV/c^{2}$.

Reduced transverse mass ($m_{t}-m_{0}$) spectra of $K^{0}_{S}$ for the 0-40% most central events.

Reduced transverse mass ($m_{t}-m_{0}$) spectra of $K^{0}_{S}$ for the 0-40% most central events. NOTE: The spectra are not scaled by $1/N_{Events}$! To compare the data, divide by $N_{Events} = 2.1997626 x 10^{9}$

Reduced transverse mass ($m_{t}-m_{0}$) spectra of $\Lambda$ for the 0-40% most central events.

Reduced transverse mass ($m_{t}-m_{0}$) spectra of $\Lambda$ for the 0-40% most central events. NOTE: The spectra are not scaled by $1/N_{Events}$! To compare the data, divide by $N_{Events} = 2.1997626 x 10^{9}$

Rapidity distribution of $K^{0}_{S}$

Rapidity distribution of $K^{0}_{S}$

Rapidity distribution of $\Lambda$

Rapidity distribution of $\Lambda$

Compilation of mid-rapidity yields for central Au+Au collisions as a function of $\sqrt{s_{NN}}$ of $K^{0}_{S}$ and $\Lambda$.

Compilation of mid-rapidity yields for central Au+Au collisions as a function of $\sqrt{s_{NN}}$ of $K^{0}_{S}$ and $\Lambda$.

Multiplicities per mean number of participants $Mult/\langle A_{Part}\rangle$ as a function of $\langle A_{Part}\rangle$

Multiplicities per mean number of participants $Mult/\langle A_{Part}\rangle$ as a function of $\langle A_{Part}\rangle$

Multiplicities per mean number of participants $Mult/\langle A_{Part}\rangle$ as a function of $\langle A_{Part}\rangle$ for $K^{0}_{S}$

Multiplicities per mean number of participants $Mult/\langle A_{Part}\rangle$ as a function of $\langle A_{Part}\rangle$ for $K^{0}_{S}$

Multiplicities per mean number of participants $Mult/\langle A_{Part}\rangle$ as a function of $\langle A_{Part}\rangle$ for $\Lambda$

Multiplicities per mean number of participants $Mult/\langle A_{Part}\rangle$ as a function of $\langle A_{Part}\rangle$ for $\Lambda$

Comparison of the shape of the rapidity distribution of $K^{0}_{S}$ to various transport model versions.

Comparison of the shape of the rapidity distribution of $K^{0}_{S}$ to various transport model versions.

Comparison of the shape of the rapidity distribution of $\Lambda$ to various transport model versions.

Comparison of the shape of the rapidity distribution of $\Lambda$ to various transport model versions.

Comparison of the shape of the $p_{t}$-spectra for $\pm0.15$ rapidity units around mid-rapidity of $K^{0}_{S}$ to various transport model versions.

Comparison of the shape of the $p_{t}$-spectra for $\pm0.15$ rapidity units around mid-rapidity of $K^{0}_{S}$ to various transport model versions.

Comparison of the shape of the $p_{t}$-spectra for $\pm0.15$ rapidity units around mid-rapidity of $\Lambda$ to various transport model versions.

Comparison of the shape of the $p_{t}$-spectra for $\pm0.15$ rapidity units around mid-rapidity of $\Lambda$ to various transport model versions.

Differential yield of $K^{0}_{S}$ as function of rapdidity and reduced transverse mass for the four centrality classes.

Differential yield of $K^{0}_{S}$ as function of rapdidity and reduced transverse mass for the four centrality classes. NOTE: The spectra are not scaled by $1/N_{Events}$! To compare the data, divide by $N_{Events} = 5.64247975 x 10^{8} (0 - 10\%)$, $5.85743394 x 10^{8} (10 - 20\%)$, $5.76369451 x 10^{8} (20 - 30\%)$ or $4.73401752 x 10^{8} (30 - 40\%)$

Differential yield of $\Lambda$ as function of rapdidity and reduced transverse mass for the four centrality classes.

Differential yield of $\Lambda$ as function of rapdidity and reduced transverse mass for the four centrality classes. NOTE: The spectra are not scaled by $1/N_{Events}$! To compare the data, divide by $N_{Events} = 5.64247975 x 10^{8} (0 - 10\%)$, $5.85743394 x 10^{8} (10 - 20\%)$, $5.76369451 x 10^{8} (20 - 30\%)$ or $4.73401752 x 10^{8} (30 - 40\%)$

Mixed higher-order flow harmonic $v_6\{\Psi_{33}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_7\{\Psi_{223}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_4\{\Psi_{22}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_5\{\Psi_{23}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{222}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{33}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_7\{\Psi_{223}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_4\{\Psi_{22}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_5\{\Psi_{23}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{222}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{33}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_7\{\Psi_{223}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_4\{\Psi_{22}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_5\{\Psi_{23}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{222}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{33}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_7\{\Psi_{223}\}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

The overall flow harmonic $v_4\{\Psi_{4}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

The overall flow harmonic $v_5\{\Psi_{5}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

The overall flow harmonic $v_6\{\Psi_{6}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

The overall flow harmonic $v_6\{\Psi_{6}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

The overall flow harmonic $v_7\{\Psi_{7}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

The overall flow harmonic $v_4\{\Psi_{4}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

The overall flow harmonic $v_5\{\Psi_{5}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

The overall flow harmonic $v_6\{\Psi_{6}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

The overall flow harmonic $v_6\{\Psi_{6}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

The overall flow harmonic $v_7\{\Psi_{7}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_4\{\Psi_{22}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_5\{\Psi_{23}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{222}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{33}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_7\{\Psi_{223}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Mixed higher-order flow harmonic $v_4\{\Psi_{22}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_5\{\Psi_{23}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{222}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_6\{\Psi_{33}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_7\{\Psi_{223}\}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{422}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{523}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{6222}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{633}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{7223}$ from the scalar-product method at 5.02 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{422}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{523}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{6222}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{633}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{7223}$ from the scalar-product method at 5.02 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{422}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{523}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{6222}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{633}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{7223}$ from the scalar-product method at 2.76 TeV as a function of PT in the 0-20% centrality range.

Nonlinear response coefficient $\chi_{422}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{523}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{6222}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{633}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

Nonlinear response coefficient $\chi_{7223}$ from the scalar-product method at 2.76 TeV as a function of PT in the 20-60% centrality range.

Mixed higher-order flow harmonic $v_4\{\Psi_{22}\}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Mixed higher-order flow harmonic $v_5\{\Psi_{23}\}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Mixed higher-order flow harmonic $v_6\{\Psi_{222}\}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Mixed higher-order flow harmonic $v_6\{\Psi_{33}\}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Mixed higher-order flow harmonic $v_7\{\Psi_{223}\}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Mixed higher-order flow harmonic $v_4\{\Psi_{22}\}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Mixed higher-order flow harmonic $v_5\{\Psi_{23}\}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Mixed higher-order flow harmonic $v_6\{\Psi_{222}\}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Mixed higher-order flow harmonic $v_6\{\Psi_{33}\}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Mixed higher-order flow harmonic $v_7\{\Psi_{223}\}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{422}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{523}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{6222}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{633}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{7223}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{422}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{523}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{6222}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{633}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{7223}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{422}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{523}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{6222}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{633}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{7223}$ from the scalar-product method at 5.02 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{422}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{523}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{6222}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{633}$ from the scalar-product method at 2.76 TeV as a function of centrality.

Nonlinear response coefficient $\chi_{7223}$ from the scalar-product method at 2.76 TeV as a function of centrality.

The cumulant $c_2\{8\}$ extracted for all charged particles with $0.3 < p_T < 3.0$ GeV/c as a function of $N_{trk}^{offline}$ in pPb collisions.

The elliptic flow $v_2\{6\}$ extracted for all charged particles with $0.3 < p_T < 3.0$ GeV/c as a function of $N_{trk}^{offline}$ in PbPb collisions.

The elliptic flow $v_2\{8\}$ extracted for all charged particles with $0.3 < p_T < 3.0$ GeV/c as a function of $N_{trk}^{offline}$ in PbPb collisions.

The elliptic flow $v_2\{\text{LYZ}\}$ extracted for all charged particles with $0.3 < p_T < 3.0$ GeV/c as a function of $N_{trk}^{offline}$ in PbPb collisions.

The elliptic flow $v_2\{6\}$ extracted for all charged particles with $0.3 < p_T < 3.0$ GeV/c as a function of $N_{trk}^{offline}$ in pPb collisions.

The elliptic flow $v_2\{8\}$ extracted for all charged particles with $0.3 < p_T < 3.0$ GeV/c as a function of $N_{trk}^{offline}$ in pPb collisions.

The elliptic flow $v_2\{\text{LYZ}\}$ extracted for all charged particles with $0.3 < p_T < 3.0$ GeV/c as a function of $N_{trk}^{offline}$ in pPb collisions.

The cumulant ratio $c_2\{6\}/v_2\{4\}$ as a function of $c_2\{4\}/v_2\{2\}$ in pPb collisions.

The cumulant ratio $c_2\{8\}/v_2\{6\}$ as a function of $c_2\{4\}/v_2\{2\}$ in pPb collisions.

The cumulant ratio $c_2\{6\}/v_2\{4\}$ as a function of $c_2\{4\}/v_2\{2\}$ in PbPb collisions.

The cumulant ratio $c_2\{8\}/v_2\{6\}$ as a function of $c_2\{4\}/v_2\{2\}$ in PbPb collisions.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.0850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.0850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.0950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.0950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.1050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.1150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1250 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.1350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.1450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.1550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.1650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1750 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.1850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.1950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.1950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.2050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.2150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2250 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.2350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.2450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.2550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.2650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2750 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.2850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.2950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.2950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.3050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.3150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3250 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.3350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.3450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.3550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.3650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3750 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.3850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.3950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.3950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.4050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.4150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4250 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.4350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.4450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.4550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.4650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4750 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.4850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.4950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.4950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.5050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.5150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5250 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.5350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.5450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.5550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.5650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5750 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.5850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.5950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.5950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.6050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.6150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6250 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.6350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.6450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.6550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.6650 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6750 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.6850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.6950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.6950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.7050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.7050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.7150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.7150 GeV.

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.7250 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 1.6000 GeV and W = 1.7350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.7350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.7450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.7550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.7650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.7850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.7950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.8050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.8150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.8350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.8450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.8550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.8650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.8850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.8950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.9050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.9150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.9350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.9450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.9550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.9650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.9850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 1.9950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.0050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.0150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.0350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.0450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.0550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.0650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.0850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.0950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.1050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.1150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.1350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.1450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.1550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.1650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.1850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.1950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.2050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.2150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.2350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.2450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.2550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.2650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.2850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.2950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.3050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.3150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.3350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.3450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.3550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.3650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.3850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.3950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.4050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.4150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.4350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.4450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.4550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.4650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.4850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.4950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.5050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.5150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.5350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.5450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.5550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.5650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.5850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.5950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.6050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.6150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.6350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.6450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.6550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.6650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.6850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.6950 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.7050 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.7150 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.7350 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.7450 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.7550 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.7650 GeV.

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

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.7850 GeV.

A1 and g1/F1 for the DEUT target at incident energy 5.7000 GeV and W = 2.7950 GeV.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.5%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.5%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.5%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.5%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.6%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.6%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-6.2%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.8%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.5%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.8%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.5%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.5%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.8%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-4.8%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-4.8%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-4.3%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-3.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-4.3%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-3.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-3.9%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-4.3%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.4%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.4%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.0%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-4.6%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.0%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-4.6%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-4.6%.

APPROXIMATE SYSTEMATIC CROSS SECTION ERROR IS EQUAL TO +-5.0%.