The K0S cross section for 5 jet ET ranges.

The LAMBDA cross section for 5 jet ET ranges.

The triple differential GAMMA+JET cross section for |y_gamma| < 1.0, |y_jet| 2.4 TO 3.2 and y_gamma*y_jet > 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| < 1.0, |y_jet| <= 0.8 and y_gamma*y_jet <= 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| < 1.0, |y_jet| 0.8 TO 1.6 and y_gamma*y_jet <= 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| < 1.0, |y_jet| 1.6 TO 2.4 and y_gamma*y_jet <= 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| < 1.0, |y_jet| 2.4 TO 3.2 and y_gamma*y_jet <= 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| 1.5 TO 2.5, |y_jet| <= 0.8 and y_gamma*y_jet > 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| 1.5 TO 2.5, |y_jet| 0.8 TO 1.6 and y_gamma*y_jet > 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| 1.5 TO 2.5, |y_jet| 1.6 TO 2.4 and y_gamma*y_jet > 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| 1.5 TO 2.5, |y_jet| 2.4 TO 3.2 and y_gamma*y_jet > 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| 1.5 TO 2.5, |y_jet| <= 0.8 and y_gamma*y_jet <= 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| 1.5 TO 2.5, |y_jet| 0.8 TO 1.6 and y_gamma*y_jet <= 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| 1.5 TO 2.5, |y_jet| 1.6 TO 2.4 and y_gamma*y_jet <= 0 A common 6.8% nomalization is included in the (sys) error.

The triple differential GAMMA+JET cross section for |y_gamma| 1.5 TO 2.5, |y_jet| 2.4 TO 3.2 and y_gamma*y_jet <= 0 A common 6.8% nomalization is included in the (sys) error.

Expected exclusion limit at 95% CL in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario.

Upper 1-sigma expected exclusion limit at 95% CL in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario.

Lower 1-sigma expected exclusion limit at 95% CL in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario.

Observed exclusion limit at 95% CL in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL, when moving the nominal signal cross section up by the 1-sigma theoretical uncertainty, in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL, when moving the nominal signal cross section down by the 1-sigma theoretical uncertainty, in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario.

Expected exclusion limit at 95% CL in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario.

Upper 1-sigma expected exclusion limit at 95% CL in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario.

Lower 1-sigma expected exclusion limit at 95% CL in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO) = 150 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL, when moving the nominal signal cross section up by the 1-sigma theoretical uncertainty, in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO) = 150 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL, when moving the nominal signal cross section down by the 1-sigma theoretical uncertainty, in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO) = 150 GEV for the stop pair production scenario.

Expected exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO) = 150 GEV for the stop pair production scenario.

Upper 1-sigma expected exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO) = 150 GEV for the stop pair production scenario.

Lower 1-sigma expected exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO) = 150 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL, when moving the nominal signal cross section up by the 1-sigma theoretical uncertainty, in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL, when moving the nominal signal cross section down by the 1-sigma theoretical uncertainty, in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario.

Expected exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario.

Upper 1-sigma expected exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario.

Lower 1-sigma expected exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL, when moving the nominal signal cross section up by the 1-sigma theoretical uncertainty, in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario.

Observed exclusion limit at 95% CL, when moving the nominal signal cross section down by the 1-sigma theoretical uncertainty, in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario.

Expected exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario.

Upper 1-sigma expected exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario.

Lower 1-sigma expected exclusion limit at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario.

Signal region (SR) providing the best expected sensitivity in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario. In the case of SRA, the number shown represents the contransverse mass, M(CT), threshold used.

Nominal observed excluded cross sections at 95% CL in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario, once corrected by the luminosity and the efficiency times acceptance of the model itself.

Impact of reducing the branching ratios of SBOTTOM --> BOTTOM NEUTRALINO, assuming no sensitivity to the other decay possibilities, in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario. The numbers represent the maximum branching ratio excluded at 95% CL, taking the nominal cross section as reference.

Signal region (SR) providing the best expected sensitivity in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario. In the case of SRA, the number shown represents the contransverse mass, M(CT), threshold used.

Signal region (SR) providing the best expected sensitivity in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario. In the case of SRA, the number shown represents the contransverse mass, M(CT), threshold used.

Signal region (SR) providing the best expected sensitivity in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario. In the case of SRA, the number shown represents the contransverse mass, M(CT), threshold used.

Nominal observed excluded cross sections at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario, once corrected by the luminosity and the efficiency times acceptance of the model itself.

Nominal observed excluded cross sections at 95% CL in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario, once corrected by the luminosity and the efficiency times acceptance of the model itself.

Nominal observed excluded cross sections at 95% CL in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario, once corrected by the luminosity and the efficiency times acceptance of the model itself.

Expected CLs values in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario.

Observed CLs values in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario.

Sbottom signal production cross sections in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane. These values are also used for the stop case since the differences in cross sections for these processes are negligible.

Relative theoretical uncertainties in percent on the sbottom signal production cross sections in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane coming from the usage of different PDF sets and renormalisation and factorisation scales. These values are also used for the stop case since the differences in cross sections for these processes are negligible.

Total number of generated MC events for the sbottom signal grid in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane.

Signal acceptance in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario. The best expected signal region selection is used per point.

Signal efficiency times acceptance in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario. The best expected signal region selection is used per point.

Total experimental systematic uncertainty in percent on the signal efficiency times acceptance in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario. All the different "up" values have been added in quadrature. The best expected signal region selection is used per point.

Total experimental systematic uncertainty in percent on the signal efficiency times acceptance in the ( M(SBOTTOM), M(NEUTRALINO) ) mass plane for the sbottom pair production scenario. All the different "down" values have been added in quadrature. The best expected signal region selection is used per point.

Expected CLs values in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario.

Expected CLs values in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario.

Expected CLs values in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario.

Observed CLs values in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario.

Observed CLs values in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario.

Observed CLs values in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario.

Total number of generated MC events for the stop signal grid in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV.

Signal acceptance in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario. The best expected signal region selection is used per point.

Signal efficiency times acceptance in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario. The best expected signal region selection is used per point.

Total experimental systematic uncertainty in percent on the signal efficiency times acceptance in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario. All the different "up" values have been added in quadrature. The best expected signal region selection is used per point.

Total experimental systematic uncertainty in percent on the signal efficiency times acceptance in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 5 GEV for the stop pair production scenario. All the different "down" values have been added in quadrature. The best expected signal region selection is used per point.

.

Signal acceptance in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario. The best expected signal region selection is used per point.

Signal efficiency times acceptance in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario. The best expected signal region selection is used per point.

Total experimental systematic uncertainty in percent on the signal efficiency times acceptance in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario. All the different "up" values have been added in quadrature. The best expected signal region selection is used per point.

Total experimental systematic uncertainty in percent on the signal efficiency times acceptance in the ( M(STOP), M(NEUTRALINO) ) mass plane with M(CHARGINO)-M(NEUTRALINO) = 20 GEV for the stop pair production scenario. All the different "down" values have been added in quadrature. The best expected signal region selection is used per point.

Total number of generated MC events for the stop signal grid in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV.

Signal acceptance in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario. The best expected signal region selection is used per point.

Signal efficiency times acceptance in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario. The best expected signal region selection is used per point.

Total experimental systematic uncertainty in percent on the signal efficiency times acceptance in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario. All the different "up" values have been added in quadrature. The best expected signal region selection is used per point.

Total experimental systematic uncertainty in percent on the signal efficiency times acceptance in the ( M(CHARGINO), M(NEUTRALINO) ) mass plane with M(STOP) = 300 GEV for the stop pair production scenario. All the different "down" values have been added in quadrature. The best expected signal region selection is used per point.

MET/sqrt(HT) distributions for the multi-jet + flavour stream with PTmin=50 GeV, and exactly nine jets, with the signal region selection, other than that on MET/sqrt(HT) itself. A selection of one-bjet is applied.

MET/sqrt(HT) distributions for the multi-jet + flavour stream with PTmin=50 GeV, and exactly eight jets, with the signal region selection, other than that on MET/sqrt(HT) itself. A selection of two or more b-jets is applied.

MET/sqrt(HT) distributions for the multi-jet + flavour stream with PTmin=50 GeV, and exactly nine jets, with the signal region selection, other than that on MET/sqrt(HT) itself. A selection of two or more b-jets is applied.

MET/sqrt(HT) distribution for the multi-jet + flavour stream with PTmin=50 GeV, and at least ten jets. The complete >=10j50 selection has been applied, other than the final MET/sqrt(HT) requirement.

MET/sqrt(HT) distributions for the multi-jet + flavour stream with pTmin=80 GeV, and exactly seven jets. The complete signal region selections were applied, other than the final MET/sqrts(HT) requirement. A selection of zero b-jets is applied.

MET/sqrts(HT) distributions for the multi-jet + flavour stream with pTmin=80 GeV, and at least eight jets. The complete signal region selections were applied, other than the final MET/sqrts(HT) requirement. A selection of zero b-jets is applied.

MET/(HT) distributions for the multi-jet + flavour stream with pTmin=80 GeV, and exactly seven jets. The complete signal region selections were applied, other than the final MET/sqrts(HT) requirement. A selection of one b-jet is applied.

MET/sqrts(HT) distributions for the multi-jet + flavour stream with pTmin=80 GeV, and at least eight jets. The complete signal region selections were applied, other than the final MET/sqrts(HT) requirement. A selection of one b-jet is applied.

MET/sqrts(HT) distributions for the multi-jet + flavour stream with pTmin=80 GeV, and exactly seven jets. The complete signal region selections were applied, other than the final MET/sqrts(HT) requirement. A selection of two or more b-jets is applied.

MET/sqrts(HT) distributions for the multi-jet + flavour stream with pTmin=80 GeV, and at least eight jets. The complete signal region selections were applied, other than the final MET/sqrts(HT) requirement. A selection of two or more b-jets is applied.

MET/sqrt(HT) distributions for the multi-jet + MJ(Sigma) stream with the MJ(Sigma)>340 GeV signal region selection, other than the final MET/sqrt(HT) requirement. There is a minimum multiplicity requirement of eight for the PTmin=50 GeV, R=0.4 jets.

MET/sqrt(HT) distributions for the multi-jet + MJ(Sigma) stream with the MJ(Sigma)>340 GeV signal region selection, other than the final MET/sqrt(HT) requirement. There is a minimum multiplicity requirement of nine for the PTmin=50 GeV, R=0.4 jets.

MET/sqrt(HT) distributions for the multi-jet + MJ(Sigma) stream with the MJ(Sigma)>340 GeV signal region selection, other than the final MET/sqrt(HT) requirement. There is a minimum multiplicity requirement of ten for the PTmin=50 GeV, R=0.4 jets.

MET/sqrt(HT) distributions for the multi-jet + MJ(Sigma) stream with the MJ(Sigma)>420 GeV signal region selection, other than the final MET/sqrt(HT) requirement. There is a minimum multiplicity requirement of eight for the PTmin=50 GeV, R=0.4 jets.

MET/sqrt(HT) distributions for the multi-jet + MJ(Sigma) stream with the MJ(Sigma)>420 GeV signal region selection, other than the final MET/sqrt(HT) requirement. There is a minimum multiplicity requirement of nine for the PTmin=50 GeV, R=0.4 jets.

MET/sqrt(HT) distributions for the multi-jet + MJ(Sigma) stream with the MJ(Sigma)>420 GeV signal region selection, requirement. There is a minimum multiplicity requirement of ten for the PTmin=50 GeV, R=0.4 jets.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.16-1.17, 1.17-1.18 and 1.18-1.19.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.19-1.20, 1.20-1.21 and 1.21-1.22.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.22-1.23, 1.23-1.24 and 1.24-1.25.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.25-1.26, 1.26-1.27 and 1.27-1.28.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.28-1.29, 1.29-1.30 and 1.30-1.31.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.31-1.32, 1.32-1.33 and 1.33-1.34.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.34-1.35, 1.35-1.36 and 1.36-1.37.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.37-1.38, 1.38-1.39 and 1.39-1.40.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.40-1.41, 1.41-1.42 and 1.42-1.43.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.43-1.44, 1.44-1.45 and 1.45-1.46.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.46-1.47, 1.47-1.48 and 1.48-1.49.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.49-1.50, 1.50-1.51 and 1.51-1.52.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.52-1.53, 1.53-1.54 and 1.54-1.55.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.55-1.56, 1.56-1.57 and 1.57-1.58.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.58-1.59, 1.59-1.60 and 1.60-1.61.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.61-1.62, 1.62-1.63 and 1.63-1.64.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.64-1.65, 1.65-1.66 and 1.66-1.67.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.67-1.68, 1.68-1.69 and 1.69-1.70.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.70-1.71, 1.71-1.72 and 1.72-1.73.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.73-1.74, 1.74-1.75 and 1.75-1.76.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.76-1.77, 1.77-1.78 and 1.78-1.79.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.79-1.80, 1.80-1.81 and 1.81-1.82.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.82-1.83, 1.83-1.84 and 1.84-1.85.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.85-1.86, 1.86-1.87 and 1.87-1.88.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.88-1.89, 1.89-1.90 and 1.90-1.92.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.92-1.94, 1.94-1.96 and 1.96-1.98.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.98-2.00, 2.00-2.02 and 2.02-2.04.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.04-2.06, 2.06-2.08 and 2.08-2.10.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.10-2.12, 2.12-2.14 and 2.14-2.16.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.16-2.18, 2.18-2.20 and 2.20-2.22.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.22-2.24, 2.24-2.26 and 2.26-2.28.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.28-2.30, 2.30-2.32 and 2.32-2.34.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.34-2.36, 2.36-2.38 and 2.38-2.40.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.40-2.44, 2.44-2.48 and 2.48-2.52.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.52-2.56, 2.56-2.60 and 2.60-2.70.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.70-2.80, 2.80-2.90 and 2.90-3.00.

The cos(Theta*) dependence of the differential cross section for the W ranges 3.00-3.10, 3.10-3.20 and 3.20-3.30.

The measured bin-averaged cross-section $d\sigma/d\Delta\phi^{\gamma \rm j}$ for isolated-photon plus jet production. Other details as in the caption to Table 1.

The measured bin-averaged cross-section $d\sigma/d{\rm m}^{\gamma \rm j}$ with the requirements on $|\cos{\Theta^{\gamma \rm J}}|$ and $|\eta^\gamma + {\rm y^{jet}}|$ for isolated-photon plus jet production. Other details as in the caption to Table 1.

The measured bin-averaged cross-section $d\sigma/d|\cos{\Theta^{\gamma \rm j}}|$ with the requirements on ${\rm m}^{\gamma \rm J}$ and $|\eta^\gamma + {\rm y^{jet}}|$ for isolated-photon plus jet production. Other details as in the caption to Table 1.

The measured bin-averaged cross-section $d\sigma/d|\cos{\Theta^{\gamma \rm j}}|$ without the requirements on ${\rm m}^{\gamma \rm J}$ and $|\eta^\gamma + {\rm y^{jet}}|$ for isolated-photon plus jet production. Other details as in the caption to Table 1.

Double-differential cross-section $d^2\sigma/dp_T/dy$ for prompt $J/\psi$ production in bins of $p_T$ and $y$, with statistical, systematic and polarization uncertainties.

Lambda-Phi in the CS frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta-Phi in the CS frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta-Phi in the CS frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Tilde in the CS frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Tilde in the CS frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta in the HX frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta in the HX frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Phi in the HX frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Phi in the HX frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta-Phi in the HX frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta-Phi in the HX frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Tilde in the HX frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Tilde in the HX frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta in the PX frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta in the PX frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Phi in the PX frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Phi in the PX frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta-Phi in the PX frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta-Phi in the PX frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Tilde in the PX frame for the J/psi as a function of pT for 0.0 < |y| < 0.6.

Lambda-Tilde in the PX frame for the J/psi as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta in the CS frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta in the CS frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta in the CS frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Phi in the CS frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Phi in the CS frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Phi in the CS frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Theta-Phi in the CS frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta-Phi in the CS frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta-Phi in the CS frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Tilde in the CS frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Tilde in the CS frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Tilde in the CS frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Theta in the HX frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta in the HX frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta in the HX frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Phi in the HX frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Phi in the HX frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Phi in the HX frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Theta-Phi in the HX frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta-Phi in the HX frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta-Phi in the HX frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Tilde in the HX frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Tilde in the HX frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Tilde in the HX frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Theta in the PX frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta in the PX frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta in the PX frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Phi in the PX frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Phi in the PX frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Phi in the PX frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Theta-Phi in the PX frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Theta-Phi in the PX frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Theta-Phi in the PX frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Lambda-Tilde in the PX frame for the psi(2S) as a function of pT for 0.0 < |y| < 0.6.

Lambda-Tilde in the PX frame for the psi(2S) as a function of pT for 0.6 < |y| < 1.2.

Lambda-Tilde in the PX frame for the psi(2S) as a function of pT for 1.2 < |y| < 1.5.

Integrated jet shape as a function of the radius r for the PT range 40-50 GeV.

Differential jet shape as a function of the radius r for the PT range 50-70 GeV.

Integrated jet shape as a function of the radius r for the PT range 50-70 GeV.

Differential jet shape as a function of the radius r for the PT range 70-100 GeV.

Integrated jet shape as a function of the radius r for the PT range 70-100 GeV.

Differential jet shape as a function of the radius r for the PT range 100-150 GeV.

Integrated jet shape as a function of the radius r for the PT range 100-150 GeV.