The distributions of the transfer factor ($\alpha$) versus $m_T$ in the HP VBF category is shown. The last bin corresponds to the value obtained by integrating events above the penultimate bin.

The distributions of the transfer factor ($\alpha$) versus $m_T$ in the HP ggF/DY category is shown. The last bin corresponds to the value obtained by integrating events above the penultimate bin.

The distributions of the transfer factor ($\alpha$) versus $m_T$ in the LP VBF category is shown. The last bin corresponds to the value obtained by integrating events above the penultimate bin.

The distributions of the transfer factor ($\alpha$) versus $m_T$ in the LP ggF/DY category is shown. The last bin corresponds to the value obtained by integrating events above the penultimate bin.

Distributions of mT for high-purity ggF/DY CR events after performing background-only fits. The last bin corresponds to the yields integrated above the penultimate bin. Both the ggF and VBF-produced 1 TeV graviton signals (normalized to 10 fb) are shown in the plot. Nonresonant background corresponds to the Z+jets and W+jets events. Resonant background corresponds to the ttbar, single top, and di/tri-boson events.

Distributions of mT for high-purity VBF CR events after performing background-only fits. The last bin corresponds to the yields integrated above the penultimate bin. Both the ggF and VBF-produced 1 TeV graviton signals (normalized to 10 fb) are shown in the plot. Nonresonant background corresponds to the Z+jets and W+jets events. Resonant background corresponds to the ttbar, single top, and di/tri-boson events.

Distributions of mT for low-purity ggF/DY CR events after performing background-only fits. The last bin corresponds to the yields integrated above the penultimate bin. Both the ggF and VBF-produced 1 TeV graviton signals (normalized to 10 fb) are shown in the plot. Nonresonant background corresponds to the Z+jets and W+jets events. Resonant background corresponds to the ttbar, single top, and di/tri-boson events.

Distributions of mT for low-purity VBF CR events after performing background-only fits. The last bin corresponds to the yields integrated above the penultimate bin. Both the ggF and VBF-produced 1 TeV graviton signals (normalized to 10 fb) are shown in the plot. Nonresonant background corresponds to the Z+jets and W+jets events. Resonant background corresponds to the ttbar, single top, and di/tri-boson events.

Distributions of mT for high-purity ggF/DY SR events after performing background-only fits. The last bin corresponds to the yields integrated above the penultimate bin. Both the ggF and VBF-produced 1 TeV graviton signals (normalized to 10 fb) are shown in the plot. Nonresonant background corresponds to the Z+jets and W+jets events. Resonant background corresponds to the ttbar, single top, and di/tri-boson events.

Distributions of mT for high-purity VBF SR events after performing background-only fits. The last bin corresponds to the yields integrated above the penultimate bin. Both the ggF and VBF-produced 1 TeV graviton signals (normalized to 10 fb) are shown in the plot. Nonresonant background corresponds to the Z+jets and W+jets events. Resonant background corresponds to the ttbar, single top, and di/tri-boson events.

Distributions of mT for low-purity ggF/DY SR events after performing background-only fits. The last bin corresponds to the yields integrated above the penultimate bin. Both the ggF and VBF-produced 1 TeV graviton signals (normalized to 10 fb) are shown in the plot. Nonresonant background corresponds to the Z+jets and W+jets events. Resonant background corresponds to the ttbar, single top, and di/tri-boson events.

Distributions of mT for low-purity VBF SR events after performing background-only fits. The last bin corresponds to the yields integrated above the penultimate bin. Both the ggF and VBF-produced 1 TeV graviton signals (normalized to 10 fb) are shown in the plot. Nonresonant background corresponds to the Z+jets and W+jets events. Resonant background corresponds to the ttbar, single top, and di/tri-boson events.

Expected and observed 95% CL upper limits on the product of the radion (R) production (gluon-gluon fusion) cross section and the R -> ZZ branching fraction versus the radion mass.

Expected and observed 95% CL upper limits on the product of the radion (R) production (vector boson fusion) cross section and the R -> ZZ branching fraction versus the radion mass.

Expected and observed 95% CL upper limits on the product of the W' (W') production (Drell-Yan) cross section and the W' -> WZ branching fraction versus the W' mass.

Expected and observed 95% CL upper limits on the product of the W' (W') production (vector boson fusion) cross section and the W' -> WZ branching fraction versus the W' mass.

Expected and observed 95% CL upper limits on the product of the graviton (G) production (gluon-gluon fusion) cross section and the G -> ZZ branching fraction versus the graviton mass.

Expected and observed 95% CL upper limits on the product of the graviton (G) production (vector boson fusion) cross section and the G -> ZZ branching fraction versus the graviton mass.

Measured values of CNN at EKIN 2035 Mev (from run period IV).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.056.

Measured values of CNN at EKIN 2115 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.046.

Measured values of CNN at EKIN 2155 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.039.

Measured values of CNN at EKIN 2175 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.041.

Measured values of CNN at EKIN 2215 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.038.

Measured values of CNN at EKIN 2225 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.049.

Measured values of CNN at EKIN 2235 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.043.

Measured values of CNN at EKIN 2245 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.048.

Measured values of CNN at EKIN 2395 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.047.

Measured values of CNN at EKIN 2445 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.049.

Measured values of CNN at EKIN 2495 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.043.

Measured values of CNN at EKIN 2515 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.044.

Measured values of CNN at EKIN 2565 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.044.

Measured values of CNN at EKIN 2575 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.044.

Measured values of CNN at EKIN 2595 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.042.

Measured values of CNN at EKIN 2645 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.043.

Measured values of CNN at EKIN 2795 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.066.

Measured values of CNN at EKIN 1955 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.086.

Measured values of CNN at EKIN 1975 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.072.

Measured values of CNN at EKIN 1995 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.101.

Measured values of CNN at EKIN 2015 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.079.

Measured values of CNN at EKIN 2035 Mev (from run period I).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.070.

Measured values of CNN at EKIN 2035 Mev (from run period II).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.065.

Measured values of CNN at EKIN 2055 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.070.

Measured values of CNN at EKIN 2075 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.064.

Measured values of CNN at EKIN 2095 Mev (from run period I).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.068.

Measured values of CNN at EKIN 2095 Mev (from run period II).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.050.

Measured values of CNN at EKIN 2115 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.071.

Measured values of CNN at EKIN 2135 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.070.

Measured values of CNN at EKIN 2155 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.067.

Measured values of CNN at EKIN 2175 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.067.

Measured values of CNN at EKIN 2205 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.073.

Measured values of CNN at EKIN 2215 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.085.

Measured values of CNN at EKIN 2225 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.070.

Measured values of CNN at EKIN 2235 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.066.

The PN analysing power of polarized protons scattered on the polarized and/or unpolarized LiD and LiH targets.

The PN analysing power of polarized protons scattered on the polarized and/or unpolarized LiD and LiH targets.

The PN analysing power of polarized protons scattered on the polarized and/or unpolarized LiD and LiH targets.

The PN analysing power of polarized protons scattered on the polarized and/or unpolarized LiD and LiH targets.

The PN analysing power of polarized protons scattered on neutrons bound in carbon nuclei in the CH2 target.

The PN spin correlation parameter CNN of polarized protons scattered on polarized neutrons bound in the LiD target. The target polarization uncertainty is 4 PCT at 1.095 GeV and 10 PCT at 1.595 GeV.

The PN spin correlation parameter CNN of polarized protons scattered on polarized neutrons bound in the LiD target. The target polarization uncertainty is 4 PCT at 1.095 GeV and 10 PCT at 1.595 GeV.

The depolarization parameter DNN for quasi-elastic PN scattering of polarized protons on LiD and LiH targets. The relative systematic error provided by thenormalization uncertainty in the P-C analysing power is 6 PCT.

The depolarization parameter DNN for quasi-elastic PN scattering of polarized protons on LiD and LiH targets. The relative systematic error provided by thenormalization uncertainty in the P-C analysing power is 6 PCT.

The depolarization parameter DNN for quasi-elastic PN scattering of polarized protons on LiD and LiH targets. The relative systematic error provided by thenormalization uncertainty in the P-C analysing power is 6 PCT.

The depolarization parameter DNN for quasi-elastic PN scattering of polarized protons on LiD and LiH targets. The relative systematic error provided by thenormalization uncertainty in the P-C analysing power is 6 PCT.

The depolarization parameter DNN for quasi-elastic PN scattering of polarized protons on LiD and LiH targets. The relative systematic error provided by thenormalization uncertainty in the P-C analysing power is 6 PCT.

The depolarization parameter DNN for quasi-elastic PN scattering of polarized protons on LiD and LiH targets. The relative systematic error provided by thenormalization uncertainty in the P-C analysing power is 6 PCT.

The depolarization parameter DNN for quasi-elastic PN scattering of polarized protons on LiD and LiH targets. The relative systematic error provided by thenormalization uncertainty in the P-C analysing power is 6 PCT.

Analysing power measurements in the scattering of polarized protons from either hydrogen in the LiH target or on bound protons in the LiD target. The three sets of results are independent.

Analysing power measurements in the scattering of polarized protons from either hydrogen in the LiH target or on bound protons in the LiD target. The three sets of results are independent.

Analysing power measurements in the scattering of polarized protons from either hydrogen in the LiH target or on bound protons in the LiD target. The three sets of results are independent.

Analysing power measurements in the scattering of polarized protons from either hydrogen in the LiH target or on bound protons in the LiD target. The three sets of results are independent.

The P P analysing power in elastic and quasi-elastic scattering on free (C=H) and strongly bound (C=C) protons in the CH2 target. All results are independent.

The P P analysing power in elastic and quasi-elastic scattering on free (C=H) and strongly bound (C=C) protons in the CH2 target. All results are independent.

The P P analysing power in elastic and quasi-elastic scattering on free (C=H) and strongly bound (C=C) protons in the CH2 target. All results are independent.

The P P analysing power in elastic and quasi-elastic scattering on free (C=H) and strongly bound (C=C) protons in the CH2 target. All results are independent.

The P P analysing power in elastic and quasi-elastic scattering on free (C=H) and strongly bound (C=C) protons in the CH2 target. All results are independent.

The P P analysing power in elastic and quasi-elastic scattering on free (C=H) and strongly bound (C=C) protons in the CH2 target. All results are independent.

The P P analysing power in elastic and quasi-elastic scattering on free (C=H) and strongly bound (C=C) protons in the CH2 target. All results are independent.

The spin correlation parameter CNN in the scattering of polarized protons from polarized hydrogen in the LiH target (C=H). At 1.095 GeV to uncertainty in the target polarization is 4 PCT.

The spin correlation parameter CNN in the scattering of polarized protons from polarized bound protons in the LiD target (Li+D(+H)). At 1.095 GeV to uncertainty in the target polarization is 4 PCT.

The spin correlation parameter CNN in the scattering of polarized protons from polarized bound protons in the LiD target (Li+D(+H)). At 1.095 GeV to uncertainty in the target polarization is 4 PCT.

The depolarization parameter DNN from elastic scattering of polarized protons on the polarized LiH target. The relative systematic error provided by the normalization uncertainty in the P-C analysing power is +- 6 PCT. There is also a +- 15 PCT uncertainty due to the relative normalization of measurements with the two opposite, (and small) target polarization values.

The polarization transfer parameter KNN measured with polarized protons on the polarized LiH and LiD targets. The relative uncertainty due to the P-C analysing power is +- 6 PCT.

The polarization transfer parameter KNN measured with polarized protons on the polarized LiD target. The relative uncertainty due to the P-C analysing power is +- 6 PCT.

The polarization transfer parameter KNN measured with polarized protons on the polarized LiD target. The relative uncertainty due to the P-C analysing power is +- 6 PCT.

The polarization transfer parameter KNN measured with polarized protons on the polarized LiH and LiD targets. The relative uncertainty due to the P-C analysing power is +- 6 PCT.

The polarization transfer parameter KNN measured with polarized protons on the polarized LiH and LiD targets. The relative uncertainty due to the P-C analysing power is +- 6 PCT.

The polarization transfer parameter KNN measured with polarized protons on the polarized LiH and LiD targets. The relative uncertainty due to the P-C analysing power is +- 6 PCT.

The polarization transfer parameter KNN measured with polarized protons on the polarized LiH and LiD targets. The relative uncertainty due to the P-C analysing power is +- 6 PCT.

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Measurement of the rescattering parameter HSNS with the beam polarisation in the +- S direction and the target polarisation in the +- N direction. Additional 7.4 PCT systematic error.

Measurement of the rescattering parameter HSNS with the beam polarisation in the +- S direction and the target polarisation in the +- N direction. Additional 7.4 PCT systematic error.

Measurement of the rescattering parameter DLS with the beam polarisation inthe +- S direction and the target polarisation in the +- L direction. Additional 6.7 PCT systematic error.

Measurement of the rescattering parameter DLS with the beam polarisation inthe +- S direction and the target polarisation in the +- L direction. Additional 6.7 PCT systematic error.

Measurement of the rescattering parameter HSLN with the beam polarisation in the +- S direction and the target polarisation in the +- L or +- N directions. Additional 7.4 PCT systematic uncertainty.

Measurement of the rescattering parameter HSLN with the beam polarisation in the +- S direction and the target polarisation in the +- L or +- N directions. Additional 7.4 PCT systematic uncertainty.

Measurement of the rescattering parameters DNN and KNN for the beam and target polarisations in the +- N directions. Additional 6.7 PCT systematic error.

Measurement of the rescattering parameters DNN and KNN for the beam and target polarisations in the +- N directions. Additional 6.7 PCT systematic error.

Measurement of the rescattering parameters DNN and KNN for the beam and target polarisations in the +- N directions. Additional 6.7 PCT systematic error.

Measurement of the rescattering parameters DNN and KNN for the beam and target polarisations in the +- N directions. Additional 6.7 PCT systematic error.