Double-differential cross section times the dimuon branching fraction of the Y(2S) meson for different ranges of pT in bins of |y| and for the full |y| < 1.2 range, for the unpolarized decay hypothesis. The global uncertainty in the integrated luminosity of 2.3% is not included in the systematic uncertainties.

Double-differential cross section times the dimuon branching fraction of the Y(3S) meson for different ranges of pT in bins of |y| and for the full |y| < 1.2 range, for the unpolarized decay hypothesis. The global uncertainty in the integrated luminosity of 2.3% is not included in the systematic uncertainties.

Multiplicative scaling factors to obtain the J/psi differential cross sections for different polarization scenarios (Lambda_{Theta} = +1, +0.10, -1) from the unpolarized cross section measurements given in Table 1.

Multiplicative scaling factors to obtain the psi(2S) differential cross sections for different polarization scenarios (Lambda_{Theta} = +1, +0.03, -1) from the unpolarized cross section measurements given in Table 2.

Multiplicative scaling factors to obtain the Y(1S) differential cross sections for different polarization scenarios (Lambda_{Theta} = +1, k, -1) from the unpolarized cross section measurements given in Table 3. The parameter k corresponds to a linear interpolation of the CMS measured value as a function of pT for pT < 50 GeV. For pT > 50 GeV, where no measurements exist, k is taken as the average of all the measured values for pT < 50 GeV.

Multiplicative scaling factors to obtain the Y(2S) differential cross sections for different polarization scenarios (Lambda_{Theta} = +1, k, -1) from the unpolarized cross section measurements given in Table 3. The parameter k corresponds to a linear interpolation of the CMS measured value as a function of pT for pT < 50 GeV. For pT > 50 GeV, where no measurements exist, k is taken as the average of all the measured values for pT < 50 GeV.

Multiplicative scaling factors to obtain the Y(3S) differential cross sections for different polarization scenarios (Lambda_{Theta} = +1, k, -1) from the unpolarized cross section measurements given in Table 3. The parameter k corresponds to a linear interpolation of the CMS measured value as a function of pT for pT < 50 GeV. For pT > 50 GeV, where no measurements exist, k is taken as the average of all the measured values for pT < 50 GeV.

Ratio of differential cross section times branching fractions of the prompt psi(2S) to J/psi mesons assuming unpolarized productions as a function of pT for |y| < 1.2.

Ratios of differential cross section times branching fractions of the prompt Y(2S) to Y(1S) and Y(3S) to Y(1S) mesons assuming unpolarized productions as a function of pT for |y| < 1.2.

The electron channel Born-level single-differential cross section DSIG/DM. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-". The ratio of the dressed-level to Born-level predictions (kDressed) is also provided.

The electron channel Born-level double-differential cross section D2SIG/DM/DABSYRAP. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-". The ratio of the dressed-level to Born-level predictions (kDressed) is also provided.

The electron channel Born-level double-differential cross section D2SIG/DM/DABSDETA. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-". The ratio of the dressed-level to Born-level predictions (kDressed) is also provided.

The muon channel Born-level single-differential cross section DSIG/DM. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-". The ratio of the dressed-level to Born-level predictions (kdressed) is also provided.

The muon channel Born-level double-differential cross section D2SIG/DM/DABSYRAP. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-". The ratio of the dressed-level to Born-level predictions (kdressed) is also provided.

The muon channel Born-level double-differential cross section D2SIG/DM/DABSDETA. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-". The ratio of the dressed-level to Born-level predictions (kdressed) is also provided.

Born-level differential fiducial cross section prediction DSIG/DM at NNLO including NLO electroweak corrections and the PI contribution. The calculation is performed using the MMHT2014 NNLO PDF set and with dynamic scales set equal to the invariant mass. The predictions are listed together with the statistical uncertainty, the PDF eigenvector variation, the uncertainty from the variation of alpha_s, the combined uncertainty from mu_F and mu_R, and the uncertainty from the variation of the photon PDF in the PI contribution. The fraction of the PI contribution, f(PI), is also given.

Born-level differential fiducial cross section prediction D2SIG/DM/DABSYRAP at NNLO including NLO electroweak corrections and the PI contribution. The calculation is performed using the MMHT2014 NNLO PDF set and with dynamic scales set equal to the invariant mass. The predictions are listed together with the statistical uncertainty, the PDF eigenvector variation, the uncertainty from the variation of alpha_s, the combined uncertainty from mu_F and mu_R, and the uncertainty from the variation of the photon PDF in the PI contribution. The fraction of the PI contribution, f(PI), is also given.

Born-level differential fiducial cross section prediction D2SIG/DM/DABSDETA at NNLO including NLO electroweak corrections and the PI contribution. The calculation is performed using the MMHT2014 NNLO PDF set and with dynamic scales set equal to the invariant mass. The predictions are listed together with the statistical uncertainty, the PDF eigenvector variation, the uncertainty from the variation of alpha_s, the combined uncertainty from mu_F and mu_R, and the uncertainty from the variation of the photon PDF in the PI contribution. The fraction of the PI contribution, f(PI), is also given.

Statistical correlation between the measurement bins in mass, absolute rapidity and absolute pseudorapidity separation in the electron channel for 116 GeV < M(EE) < 150 GeV.

Statistical correlation between the measurement bins in mass, absolute rapidity and absolute pseudorapidity separation in the electron channel for 150 GeV < M(EE) < 200 GeV.

Statistical correlation between the measurement bins in mass, absolute rapidity and absolute pseudorapidity separation in the electron channel for 200 GeV < M(EE) < 300 GeV.

Statistical correlation between the measurement bins in mass, absolute rapidity and absolute pseudorapidity separation in the electron channel for 300 GeV < M(EE) < 500 GeV.

Statistical correlation between the measurement bins in mass, absolute rapidity and absolute pseudorapidity separation in the electron channel for 500 GeV < M(EE) < 1500 GeV.

The electron channel dressed-level single-differential cross section DSIG/DM. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 116 GeV < M(EE) < 150 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 150 GeV < M(EE) < 200 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 200 GeV < M(EE) < 300 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 300 GeV < M(EE) < 500 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 500 GeV < M(EE) < 1500 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel Born-level double-differential cross section D2SIG/DM/DABSDETA in the bin 116 GeV < M(EE) < 150 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel Born-level double-differential cross section D2SIG/DM/DABSDETA in the bin 150 GeV < M(EE) < 200 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel Born-level double-differential cross section D2SIG/DM/DABSDETA in the bin 200 GeV < M(EE) < 300 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel Born-level double-differential cross section D2SIG/DM/DABSDETA in the bin 300 GeV < M(EE) < 500 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The electron channel Born-level double-differential cross section D2SIG/DM/DABSDETA in the bin 500 GeV < M(EE) < 1500 GeV. The measurements are listed together with the statistical uncertainties. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), electron reconstruction efficiency (reco), electron identification efficiency (id), the isolation efficiency (iso), the electron energy resolution (Eres), the electron energy scale (Escale), the multijet and W+jets background (mult.), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level single-differential cross section DSIG/DM. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 116 GeV < M(MM) < 150 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 150 GeV < M(MM) < 200 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 200 GeV < M(MM) < 300 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 300 GeV < M(MM) < 500 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSYRAP in the bin 500 GeV < M(MM) < 1500 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSDETA in the bin 116 GeV < M(MM) < 150 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSDETA in the bin 150 GeV < M(MM) < 200 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSDETA in the bin 200 GeV < M(MM) < 300 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSDETA in the bin 300 GeV < M(MM) < 500 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

The muon channel dressed-level double-differential cross section D2SIG/DM/DABSDETA in the bin 500 GeV < M(MM) < 1500 GeV. The measurements are listed together with the statistical (stat) uncertainty. In addition the contributions from the individual correlated (cor) and uncorrelated (unc) systematic error sources are also provided consisting of the trigger efficiency (trig), muon reconstruction efficiency (reco), the MS resolution (MSres), the ID resolution (IDres), the muon transverse momentum scale (pT), the isolation efficiency (iso), the top and diboson background normalisation (top, diboson), the top and diboson background MC statistical uncertainty (bgMC), the multijet background uncertainty (mult), the signal MC statistical uncertainty (MC), and the luminosity uncertainty (lumi). The sign of the uncertainty corresponds to a one standard deviation upward shift of the uncertainty source, where +/- means "+" and -/+ means "-".

Summary of results for cross-section of non-prompt $J/\psi$ decaying to a muon pair for 8 TeV data in nb/GeV. Uncertainties are statistical and systematic, respectively.

Summary of results for cross-section of prompt $\psi(2S)$ decaying to a muon pair for 7 TeV data in nb/GeV. Uncertainties are statistical and systematic, respectively.

Summary of results for cross-section of prompt $\psi(2S)$ decaying to a muon pair for 8 TeV data in nb/GeV. Uncertainties are statistical and systematic, respectively.

Summary of results for cross-section of non-prompt $\psi(2S)$ decaying to a muon pair for 7 TeV data in nb/GeV. Uncertainties are statistical and systematic, respectively.

Summary of results for cross-section of non-prompt $\psi(2S)$ decaying to a muon pair for 8 TeV data in nb/GeV. Uncertainties are statistical and systematic, respectively.

Summary of results for non-prompt fraction of $J/\psi$ decaying to a muon pair as a percentage for 7 TeV data. Uncertainties are statistical and systematic, respectively.

Summary of results for non-prompt fraction of $J/\psi$ decaying to a muon pair as a percentage for 8 TeV data. Uncertainties are statistical and systematic, respectively.

Summary of results for non-prompt fraction of $\psi(2S)$ decaying to a muon pair as a percentage for 7 TeV data. Uncertainties are statistical and systematic, respectively.

Summary of results for non-prompt fraction of $\psi(2S)$ decaying to a muon pair as a percentage for 8 TeV data. Uncertainties are statistical and systematic, respectively.

Summary of results for prompt $\psi(2S)$ over $J/\psi$ ratio as a percentage for 7 TeV data. Uncertainties are statistical and systematic, respectively.

Summary of results for prompt $\psi(2S)$ over $J/\psi$ ratio as a percentage for 8 TeV data. Uncertainties are statistical and systematic, respectively.

Summary of results for non-prompt $\psi(2S)$ over $J/\psi$ ratio as a percentage for 7 TeV data. Uncertainties are statistical and systematic, respectively.

Summary of results for non-prompt $\psi(2S)$ over $J/\psi$ ratio as a percentage for 8 TeV data. Uncertainties are statistical and systematic, respectively.

Mean weight correction factor for $J/\psi$ under the "longitudinal" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $J/\psi$ under the "transverse zero" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $J/\psi$ under the "transverse positive" spin-alignment transverse positive hypothesis for 7 TeV.

Mean weight correction factor for $J/\psi$ under the "transverse negative" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $J/\psi$ under the "off-($\lambda_{\theta}$--$\lambda_{\phi}$)-plane positive" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $J/\psi$ under the "off-($\lambda_{\theta}$--$\lambda_{\phi}$)-plane negative" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $\psi(2S)$ under the "longitudinal" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $\psi(2S)$ under the "transverse zero" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $\psi(2S)$ under the "transverse positive" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $\psi(2S)$ under the "transverse negative" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $\psi(2S)$ under the "off-($\lambda_{\theta}$--$\lambda_{\phi}$)-plane positive" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $\psi(2S)$ under the "off-($\lambda_{\theta}$--$\lambda_{\phi}$)-plane negative" spin-alignment hypothesis for 7 TeV.

Mean weight correction factor for $J/\psi$ under the "longitudinal" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $J/\psi$ under the "transverse zero" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $J/\psi$ under the "transverse positive" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $J/\psi$ under the "transverse negative" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $J/\psi$ under the "off-($\lambda_{\theta}$--$\lambda_{\phi}$)-plane positive" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $J/\psi$ under the "off-($\lambda_{\theta}$--$\lambda_{\phi}$)-plane negative" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $\psi(2S)$ under the "longitudinal" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $\psi(2S)$ under the "transverse zero" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $\psi(2S)$ under the "transverse positive" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $\psi(2S)$ under the "transverse negative" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $\psi(2S)$ under the "off-($\lambda_{\theta}$--$\lambda_{\phi}$)-plane positive" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

Mean weight correction factor for $\psi(2S)$ under the "off-($\lambda_{\theta}$--$\lambda_{\phi}$)-plane negative" spin-alignment hypothesis for 8 TeV. Those intervals not measured in the analysis at low $p_{T}$, high rapidity are also excluded here.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The effective exponential slope, $b_n$, obtained from the fit of double differential photoproduction cross sections ${\rm d^2}\sigma_{\gamma p}/{\rm d}x_L{\rm d}p_{T,n}^2$ to a single exponential function in bins of $x_L$. The first uncertainty represents the fit error from the statistical and uncorrelated systematic uncertainty and the second one is due to the correlated systematic uncertainty.

Energy dependence of the exclusive photoproduction of a $\rho^0$ meson associated with a leading neutron, $\gamma p \to \rho^0 n \pi^+$. The first uncertainty is statistical and the second is systematic. The global normalisation uncertainty of $4.4\%$ is not included. $\Phi_{\gamma}$ is the integral of the photon flux, Eq. (3) of paper, in a given $W_{\gamma p}$ bin.

Differential photoproduction cross section ${\rm d}\sigma_{\gamma p}/{\rm d}\eta$ for the exclusive process $\gamma p \to \rho^0 n \pi^+$ as a function of the $\rho^0$ pseudorapidity in the kinematic range $0.35 < x_L < 0.95$, $\theta_n < 0.75$ mrad and $20 < W_{\gamma p} < 100$ GeV. The statistical, uncorrelated and correlated systematic uncertainties, $\delta_{stat}$, $\delta_{sys}^{unc}$ and $\delta_{sys}^{cor}$ respectively, are given, which does not include the global normalisation error of $4.4\%$.

Differential photoproduction cross section ${\rm d}\sigma_{\gamma p}/{\rm d}t^{\prime}$ for the exclusive process $\gamma p \to \rho^0 n \pi^+$ as a function of the $\rho^0$ four-momentum transfer squared, $t^{\prime}$, in the kinematic range $0.35 < x_L < 0.95$, $\theta_n < 0.75$ mrad and $20 < W_{\gamma p} < 100$ GeV. The statistical, uncorrelated and correlated systematic uncertainties, $\delta_{stat}$, $\delta_{sys}^{unc}$ and $\delta_{sys}^{cor}$ respectively, are given, which does not include the global normalisation error of $4.4\%$.

Exponential slopes, $b_1$ and $b_2$, and the ratio $\sigma_1/\sigma_2$, obtained from the components of fit, Eq. (14) of paper, to the differential cross section ${\rm d}\sigma_{\gamma p}/{\rm d}t^{\prime}$ in bins of $x_L$. The errors represent the statistical and systematic uncertainties added in quadrature.

Exponential slopes, $b_1$ and $b_2$, and the ratio $\sigma_1/\sigma_2$, obtained from the components of fit, Eq. (14) of paper, to the differential cross section ${\rm d}\sigma_{\gamma p}/{\rm d}t^{\prime}$ in bins of $p_{T,n}^2$. The errors represent the statistical and systematic uncertainties added in quadrature.

Energy dependence of elastic $\rho^0$ photoproduction on the pion, $\gamma \pi^+ \to \rho^0 \pi^+$, extracted in the one-pion-exchange approximation using OPE1 sample. The first uncertainty represents the full experimental error and the second is the model error coming from the pion flux uncertainty (see text). $\Gamma_\pi(x_L)$ represents the value of the pion flux, Eqs. (5-6) of paper, integrated over the $p_{T,n}<0.2$ GeV range, at a given $x_L$.

Cross section of elastic $\rho^0$ photoproduction on the pion, $\gamma \pi^+ \to \rho^0 \pi^+$, extracted in the one-pion-exchange approximation using three different samples: full sample, OPE1 and OPE2. The first uncertainty represents the full experimental error and the second is the model error coming from the pion flux uncertainty (see text). $\Gamma_\pi$ represents the value of the pion flux, Eqs. (5-6) of paper, integrated over the corresponding $(x_L,p_{T,n})$ range.

Measured non-prompt J/psi differential cross-section multiplied by branching ratio. The first systematic uncertainty is the combined systematic uncertainty excluding luminosity, the second is the luminosity.

Measured prompt J/psi differential cross-section multiplied by branching ratio. The first systematic uncertainty is the combined systematic uncertainty excluding luminosity, the second is the luminosity.

Measured non-prompt J/psi differential cross-section multiplied by branching ratio. The first systematic uncertainty is the combined systematic uncertainty excluding luminosity, the second is the luminosity.

Measured forward-backward production ratio.

Measured forward-backward production ratio.

The combined differential $D^{*\pm}$-production cross section as a function of $Q^2$, with its uncorrelated and correlated uncertainties.

The combined differential $D^{*\pm}$-production cross section as a function of $y$, with its uncorrelated and correlated uncertainties.

The combined double-differential $D^{*\pm}$-production cross section as a function of $Q^2$ and $y$, with its uncorrelated and correlated uncertainties.

Diffractive DIS dijet cross section measured differentially as a function of $\log x_P$. The global normalisation uncertainty of $7.8\%$ is not listed explicitly but is included in the total systematic uncertainty. The last two column show the correction factors for hadronisation and QED radiation, respectively. (Note: assume typo in Table 2 that $x_P$ really means $\log x_P$.).

Diffractive DIS dijet cross section measured differentially as a function of $z_P$. The global normalisation uncertainty of $7.8\%$ is not listed explicitly but is included in the total systematic uncertainty. The last two column show the correction factors for hadronisation and QED radiation, respectively.

Diffractive DIS dijet cross section measured differentially as a function of $p^{\ast}_{T,1}$.

Diffractive DIS dijet cross section measured differentially as a function of $p^{\ast}_{T,2}$.

Diffractive DIS dijet cross section measured differentially as a function of $\langle p^{\ast}_{T}\rangle$.

Diffractive DIS dijet cross section measured differentially as a function of $\Delta\eta^{\ast}$.

Diffractive DIS dijet cross section measured differentially as a function of $z_P$ and $Q^2$.

Diffractive DIS dijet cross section measured differentially as a function of $p^{\ast}_{\rm T,1}$ and $Q^2$.