The performance of jet energy resolution (JER) for jets with |y| < 2.1 evaluated as a function of pT_truth in different centrality bins. Simulated hard scatter events were overlaid onto events from a dedicated sample of minimum-bias Xe+Xe data. The fit parameters are listed in a sperate table (Extras 1)

The relative magnitude of systematic uncertainties for per-pair normalized xJ distributions in 0-10% Xe+Xe centrality

The relative magnitude of systematic uncertainties for absolutely normalized xJ distributions in 0-10% Xe+Xe centrality

The relative magnitude of systematic uncertainties for rho distributions for leading jets in 0-10% Xe+Xe centrality

Per-pair normalized xJ distribution evaluated in four centrality intervals and given pT1 interval.

Per-pair normalized xJ distribution evaluated in four centrality intervals and given pT1 interval.

Per-pair normalized xJ distribution evaluated in four centrality intervals and given pT1 interval.

Absolutely normalized xJ distribution evaluated in four centrality intervals and given pT1 interval.

Absolutely normalized xJ distribution evaluated in four centrality intervals and given pT1 interval.

Absolutely normalized xJ distribution evaluated in four centrality intervals and given pT1 interval.

Per-pair normalized xJ distribution in Xe+Xe collisions.

Per-pair normalized xJ distribution in Pb+Pb collisions.

Per-pair normalized xJ distribution in Xe+Xe collisions.

Per-pair normalized xJ distribution in Pb+Pb collisions.

Per-pair normalized xJ distribution in Xe+Xe collisions.

Per-pair normalized xJ distribution in Pb+Pb collisions.

Absolutely normalized xJ distribution in Xe+Xe collisions.

Absolutely normalized xJ distribution in Xe+Xe collisions.

Absolutely normalized xJ distribution in Xe+Xe collisions.

Absolutely normalized xJ distribution in Xe+Xe collisions.

Absolutely normalized xJ distribution in Xe+Xe collisions.

Absolutely normalized xJ distribution in Xe+Xe collisions.

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of leading jet pT in the same centrality intervals.

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of leading jet pT in the same centrality intervals.

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of leading jet pT in the same centrality intervals.

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of subleading jet pT in the same centrality intervals.

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of subleading jet pT in the same centrality intervals.

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of subleading jet pT in the same centrality intervals.

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of leading jet pT in the same SUM ETFCal intervals (selecting equivalent event activity)

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of leading jet pT in the same SUM ETFCal intervals (selecting equivalent event activity)

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of leading jet pT in the same SUM ETFCal intervals (selecting equivalent event activity)

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of subleading jet pT in the same SUM ETFCal intervals (selecting equivalent event activity)

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of subleading jet pT in the same SUM ETFCal intervals (selecting equivalent event activity)

The ratios of Xe+Xe and Pb+Pb pair nuclear-modification factors, rho, evaluated as a function of subleading jet pT in the same SUM ETFCal intervals (selecting equivalent event activity)

Parameter a,b, and c from JER fits in Figure 1b.

Per-pair normalized xJ distribution in Xe+Xe collisions for selected Pb+Pb centrality and pT1 bin.

Per-pair normalized xJ distribution in Xe+Xe collisions for selected Pb+Pb centrality and pT1 bin.

Per-pair normalized xJ distribution in Xe+Xe collisions for selected Pb+Pb centrality and pT1 bin.

Per-pair normalized xJ distribution in Xe+Xe collisions for selected Pb+Pb centrality and pT1 bin.

Per-pair normalized xJ distribution in Xe+Xe collisions for selected Pb+Pb centrality and pT1 bin.

Per-pair normalized xJ distribution in Xe+Xe collisions for selected Pb+Pb centrality and pT1 bin.

Per-pair normalized xJ distribution in Xe+Xe collisions for selected Pb+Pb centrality and pT1 bin.

Per-pair normalized xJ distribution in Xe+Xe collisions for selected Pb+Pb centrality and pT1 bin.

Per-pair normalized xJ distribution in Xe+Xe collisions for selected Pb+Pb centrality and pT1 bin.

Nuclear modification factor for prompt charged particles at 5TeV with respect to pseudorapidity and transverse momentum in the forward region region. The pseudorapidity is expressed in the nucleon-nucleon center-of-mass system. First uncertainty is statistical, the second is systematic and the third is from the luminosity. Luminosity uncertainty is fully correlated among the different kinematic ranges.

Nuclear modification factor for prompt charged particles at 5TeV with respect to pseudorapidity and transverse momentum in the backward region region. The pseudorapidity is expressed in the nucleon-nucleon center-of-mass system. First uncertainty is statistical, the second is systematic and the third is from the luminosity. Luminosity uncertainty is fully correlated among the different kinematic ranges.

$\Upsilon(1S)$ production cross-section in $p$Pb and Pb$p$, as a function of $y^*$. The uncertainty is the sum in quadrature of the statistical and systematic components.

$\Upsilon(2S)$ production cross-section in $p$Pb and Pb$p$, as a function of $p_{T}$. The uncertainty is the sum in quadrature of the statistical and systematic components.

$\Upsilon(2S)$ production cross-section in $p$Pb and Pb$p$, as a function of $y^*$. The uncertainty is the sum in quadrature of the statistical and systematic components.

Scaled $pp$ differential cross-section in $p_{T}$ at $\sqrt{s_{NN}}=8.16$ TeV. The first uncertainty is statistical, the second is systematic, which includes the systematic uncertainty from the $pp$ measurement and that estimated by changing the interpolation function.

Scaled $pp$ differential cross-section in $y$ at $\sqrt{s_{NN}}=8.16$ TeV. The first uncertainty is statistical, the second is systematic, which includes the systematic uncertainty from the $pp$ measurement and that estimated by changing the interpolation function.

$\Upsilon(1S)$ nuclear modification factor, $R_{p{\rm Pb}}^{\Upsilon(1S)}$, in $p$Pb and Pb$p$ as a function of $p_{T}$ integrated over $y^*$ in the range $1.5 < y^* < 4.0$ for $p$Pb and $-5.0 < y^* < -2.5$ for Pb$p$. The quoted uncertainties are the sum in quadrature of the statistical and systematic components.

$\Upsilon(1S)$ nuclear modification factor, $R_{p{\rm Pb}}^{\Upsilon(1S)}$, in $p$Pb and Pb$p$ as a function of $y^*$ integrated over $p_{T}$ in the range $0 < p_{T} < 25$ GeV$/c$. The quoted uncertainties are the sum in quadrature of the statistical and systematic components.

$\Upsilon(2S)$ nuclear modification factor, $R_{p{\rm Pb}}^{\Upsilon(2S)}$, in $p$Pb and Pb$p$ as a function of $p_{T}$ integrated over $y^*$ in the range $1.5 < y^* < 4.0$ for $p$Pb and $-5.0 < y^* < -2.5$ for Pb$p$. The quoted uncertainties are the sum in quadrature of the statistical and systematic components.

$\Upsilon(2S)$ nuclear modification factor, $R_{p{\rm Pb}}^{\Upsilon(2S)}$, in $p$Pb and Pb$p$ as a function of $y^*$ integrated over $p_{T}$ in the range $0 < p_{T} < 25$ GeV$/c$. The quoted uncertainties are the sum in quadrature of the statistical and systematic components.

$\Upsilon(1S)$ forward-to-backward ratio, $R_{{\rm FB}}^{\Upsilon(1S)}$, as a function of $p_{T}$ integrated over $\vert y^* \vert$ in the range $2.5 < \vert y^* \vert < 4.0$. The quoted uncertainties are the sum in quadrature of the statistical and systematic components.

$\Upsilon(1S)$ forward-to-backward ratio, $R_{{\rm FB}}^{\Upsilon(1S)}$, as a function of $\vert y^* \vert$ integrated over $p_{T}$ in the range $0 < p_{T} < 25$ GeV/c. The quoted uncertainties are the sum in quadrature of the statistical and systematic components.

$\Upsilon(2S)$ to $\Upsilon(1S)$ ratio, in $p$Pb and Pb$p$ as a function of $p_{T}$ integrated over $y^*$ in the range $1.5 < y^* < 4.0$ for $p$Pb and $-5.0 < y^* < -2.5$ for Pb$p$. The quoted uncertainties are the sum in quadrature of the statistical and systematic components.

$\Upsilon(2S)$ to $\Upsilon(1S)$ ratio, in $p$Pb and Pb$p$ as a function of $y^*$ integrated over $p_{T}$ in the range $0 < p_{T} < 25$ GeV/c. The quoted uncertainties are the sum in quadrature of the statistical and systematic components.

$\Upsilon(1S)$ to non-prompt $J/\psi$, in $p$Pb and Pb$p$ as a function of $y^*$ integrated over $p_{T}$ in the range $0 < p_{T} < 25$ GeV/c. The quoted uncertainties are the sum in quadrature of the statistical and systematic components.

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.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 20 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 31 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 31 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 31 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 31 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 40 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 40 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 40 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 40 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 80 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 80 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 80 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 80 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 80 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Transverse momentum spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 20 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 20 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 20 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 20 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 31 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 31 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 31 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 31 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 40 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 40 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 40 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 40 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 80 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 80 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 80 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 80 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Transverse mass spectra of $\pi^-$ mesons produced in inelastic $p p$ interactions at 158 GeV in various rapidity ranges.

Inverse slope parameter T as a function of rapidity for the 5 beam momenta.

Rapidity spectra for the 5 beam momenta.

Mean transverse mass as a function of rapidity for the 5 beam momenta.

Numerical values of the parameters fitted to the rapidiy distributions.

$K^0_S$ production cross sections in the [240, 420] mrad polar interval.

$\Lambda$ production cross sections in the [20, 140] mrad polar interval.

$\Lambda$ production cross sections in the [140, 240] mrad polar interval.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.17 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.19 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.21 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.23 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.25 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.27 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.29 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.31 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.33 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.35 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.37 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.39 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.41 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.43 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.45 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.47 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.49 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.51 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.53 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.55 GeV.

Structure functions for Q**2 = 0.30 GeV**2 and W = 1.57 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.11 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.13 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.15 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.17 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.19 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.21 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.23 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.25 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.27 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.29 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.31 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.33 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.35 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.37 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.39 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.41 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.43 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.45 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.47 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.49 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.51 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.53 GeV.

Structure functions for Q**2 = 0.40 GeV**2 and W = 1.55 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.11 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.13 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.15 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.17 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.19 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.21 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.23 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.25 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.27 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.29 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.31 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.33 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.35 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.37 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.39 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.41 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.43 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.45 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.47 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.49 GeV.

Structure functions for Q**2 = 0.50 GeV**2 and W = 1.51 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.11 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.13 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.15 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.17 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.19 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.21 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.23 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.25 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.27 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.29 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.31 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.33 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.35 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.37 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.39 GeV.

Structure functions for Q**2 = 0.60 GeV**2 and W = 1.41 GeV.

Cross sections for W = 1.11 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.11 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.11 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.11 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.11 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.11 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.11 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.11 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.11 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.13 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.15 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.17 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.19 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.21 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.23 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.25 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.27 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.29 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.31 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.33 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.35 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.37 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.39 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.41 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.43 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.45 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.47 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.49 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.51 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.53 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.55 GeV**2 and THETA = 157.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 7.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 22.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 37.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 52.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 67.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 82.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 97.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 112.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 127.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 142.5 deg.

Cross sections for W = 1.57 GeV**2 and THETA = 157.5 deg.

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

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

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

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

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

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

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

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

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

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

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