$\sqrt{s} = 7$ TeV, $p_T > 500 $ MeV, $|\eta|<2$.

$\sqrt{s} = 900$ GeV, $p_T > 500 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 500 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 900$ GeV, $p_T > 500 $ MeV, $|\eta|<1$.

$\sqrt{s} = 7$ TeV, $p_T > 500 $ MeV, $|\eta|<1$.

$\sqrt{s} = 900$ GeV, $p_T > 500 $ MeV, $|\eta|<2$.

$\sqrt{s} = 7$ TeV, $p_T > 500 $ MeV, $|\eta|<2$.

$\sqrt{s} = 900$ GeV, $p_T > 500 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 500 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 100 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 200 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 300 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 500 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 1000 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 1500 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 2000 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 7$ TeV, $\eta$ interval: $0.0 - 0.5$.

$\sqrt{s} = 7$ TeV, $\eta$ interval: $0.5 - 1.0$.

$\sqrt{s} = 7$ TeV, $\eta$ interval: $1.0 - 1.5$.

$\sqrt{s} = 7$ TeV, $\eta$ interval: $1.5 - 2.0$.

$\sqrt{s} = 7$ TeV, $\eta$ interval: $2.0 - 2.5$.

$\sqrt{s} = 7$ TeV, $p_T > 100 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 900$ GeV, $p_T > 100 $ MeV, $|\eta|<2.5$.

$\sqrt{s} = 900$ GeV, $p_T > 100 $ MeV, $|\eta|<2.5$.

Identified hadron $v_2$ in midcentral (20–60%, right panels) Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. Panels (a) and (b) show $v_2$ as a function of transverse momentum $p_T$. The $v_2$ of all species for centrality 0–20% has been scaled up by a factor of 1.6 for better comparison with results of 20–60% centrality. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

Identified hadron $v_2$ in midcentral (20–60%, right panels) Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. Panels (a) and (b) show $v_2$ as a function of transverse momentum $p_T$. The $v_2$ of all species for centrality 0–20% has been scaled up by a factor of 1.6 for better comparison with results of 20–60% centrality. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

Identified hadron $v_2$ in midcentral (20–60%, right panels) Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. Panels (a) and (b) show $v_2$ as a function of transverse momentum $p_T$. The $v_2$ of all species for centrality 0–20% has been scaled up by a factor of 1.6 for better comparison with results of 20–60% centrality. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 0–10% centrality [panel (a)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 0–10% centrality [panel (a)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 0–10% centrality [panel (a)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 10–20% centrality [panel (b)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 10–20% centrality [panel (b)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 10–20% centrality [panel (b)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 20–40% centrality [panel (c)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 20–40% centrality [panel (c)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 20–40% centrality [panel (c)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 40–60% centrality [panel (d)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 40–60% centrality [panel (d)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 40–60% centrality [panel (d)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The error bars (shaded boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 10–40% centrality [panel (b)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The $v_2$ of $\Lambda$ and K$^0_S$ are measured by STAR collaboration [21]. The error bars (open boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown on the results from this study are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 10–40% centrality [panel (b)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The $v_2$ of $\Lambda$ and K$^0_S$ are measured by STAR collaboration [21]. The error bars (open boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown on the results from this study are type A and B only.

The quark-number-scaled $v_2$ ($v_2/n_q$) of identified hadrons are shown as a function of the kinetic energy per quark, KE$_T/n_q$ in 10–40% centrality [panel (b)] in Au + Au collisions at $\sqrt{s_{NN}}$ = 200 GeV. The $v_2$ of $\Lambda$ and K$^0_S$ are measured by STAR collaboration [21]. The error bars (open boxes) represent the statistical (systematic) uncertainties. The systematic uncertainties shown on the results from this study are type A and B only.

Double differential cross section for UPSI(1S) production times the dimuon branching fraction as a function of PT for the rapidity region 3.0-3.5. The second systematic (sys) error is due to the unknown polarisation of the UPSI(1S).

Double differential cross section for UPSI(1S) production times the dimuon branching fraction as a function of PT for the rapidity region 3.5-4.0. The second systematic (sys) error is due to the unknown polarisation of the UPSI(1S).

Double differential cross section for UPSI(1S) production times the dimuon branching fraction as a function of PT for the rapidity region 4.0-4.5. The second systematic (sys) error is due to the unknown polarisation of the UPSI(1S).

Double differential cross section for UPSI(2S) production times the dimuon branching fraction as a function of PT for the rapidity region 2.0-2.5. The second systematic (sys) error is due to the unknown polarisation of the UPSI(2S).

Double differential cross section for UPSI(2S) production times the dimuon branching fraction as a function of PT for the rapidity region 2.5-3.0. The second systematic (sys) error is due to the unknown polarisation of the UPSI(2S).

Double differential cross section for UPSI(2S) production times the dimuon branching fraction as a function of PT for the rapidity region 3.0-3.5. The second systematic (sys) error is due to the unknown polarisation of the UPSI(2S).

Double differential cross section for UPSI(2S) production times the dimuon branching fraction as a function of PT for the rapidity region 3.5-4.0. The second systematic (sys) error is due to the unknown polarisation of the UPSI(2S).

Double differential cross section for UPSI(2S) production times the dimuon branching fraction as a function of PT for the rapidity region 4.0-4.5. The second systematic (sys) error is due to the unknown polarisation of the UPSI(2S).

Double differential cross section for UPSI(3S) production times the dimuon branching fraction as a function of PT for the rapidity region 2.0-2.5. The second systematic (sys) error is due to the unknown polarisation of the UPSI(3S).

Double differential cross section for UPSI(3S) production times the dimuon branching fraction as a function of PT for the rapidity region 2.5-3.0. The second systematic (sys) error is due to the unknown polarisation of the UPSI(3S).

Double differential cross section for UPSI(3S) production times the dimuon branching fraction as a function of PT for the rapidity region 3.0-3.5. The second systematic (sys) error is due to the unknown polarisation of the UPSI(3S).

Double differential cross section for UPSI(3S) production times the dimuon branching fraction as a function of PT for the rapidity region 3.5-4.0. The second systematic (sys) error is due to the unknown polarisation of the UPSI(3S).

Double differential cross section for UPSI(3S) production times the dimuon branching fraction as a function of PT for the rapidity region 4.0-4.5. The second systematic (sys) error is due to the unknown polarisation of the UPSI(3S).

Ratios of cross section with respect to the UPSI(1S) cross section as a function of PT in the rapidity range 2.0-4.4. The second systematic (sys) error is due to the unknown polarisation of the three states.

The measured transverse asymmetry from the deuteron target as a function of the variable X. Mean values are also given for the variables Q**2[GeV^2], Y, Z, M[GeV], M**2[GeV^2], SIN(THETA), COS(THETA), COS(THETA)**2 and the transverse spin transfer coefficient DNN.

The measured transverse asymmetry from the deuteron target as a function of the variable Z. Mean values are also given for the variables Q**2[GeV^2], Y, X, M[GeV], M**2[GeV^2], SIN(THETA), COS(THETA), COS(THETA)**2 and the transverse spin transfer coefficient DNN.

The measured transverse asymmetry from the deuteron target as a function of the variable M. Mean values are also given for the variables Q**2[GeV^2], Y, Z, X, M**2[GeV^2], SIN(THETA), COS(THETA), COS(THETA)**2 and the transverse spin transfer coefficient DNN Note that the data in the last bin (>1.5) does not contribute to the X and Z distributions.

95% CL upper limits on the chargino mass as a function of lifetime.

Cross section of midrapidity charged-hadron production from $p$ + $p$ collisions at $\sqrt{s}$ = 62.4 GeV as a function of $p_T$ for positive and negative hadrons.

Double-helicity asymmetries and the statistical uncertainties as a function of $p_T$ for positive and negative inclusive charged hadrons from $p$ + $p$ collisions at $\sqrt{s}$ = 62.4 GeV.

The measured W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 2 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 3 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 4 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 2 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 3 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 4 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the third jet in the event for jet multiplicities >= 3 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the third jet in the event for jet multiplicities >= 4 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the fourth jet in the event for jet multiplicities >= 4 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of HT for jet multiplicities >= 1 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of HT for jet multiplicities >= 2 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of HT for jet multiplicities >= 3 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of HT for jet multiplicities >= 4 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the invariant mass of the first+second jets for jet multiplicites >= 2 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the invariant mass of the first+second+third jets for jet multiplicites >= 3 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the invariant mass of the first+second+third+fourth jets for jet multiplicites >= 4 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the rapidity of the first jet in the event for jet multiplicities >= 1 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the DeltaR(first jet,second jet) for jet multiplicites >= 2 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the |y(lepton)-y(first jet)| for jet multiplicites >= 2 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the |y(first jet)+y(second jet)| for jet multiplicites >= 2 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the |y(first jet)-y(second jet)| for jet multiplicites >= 2 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the |phi(first jet)-phi(second jet)| for jet multiplicites >= 2 and jet PT > 30 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The predicted W+jets cross section as a function of the jet multiplicity for jet PT > 30 GeV.

The predicted W+jets cross section ratio as a function of jet multiplicty for jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 1 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 2 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 3 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 4 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 2 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 3 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 4 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the third jet in the event for jet multiplicities >= 3 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the third jet in the event for jet multiplicities >= 4 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the pT of the fourth jet in the event for jet multiplicities >= 4 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of HT for jet multiplicities >= 1 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of HT for jet multiplicities >= 2 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of HT for jet multiplicities >= 3 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of HT for jet multiplicities >= 4 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the invariant mass of the first+second jets for jet multiplicites >= 2 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the invariant mass of the first+second+third jets for jet multiplicites >= 3 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the invariant mass of the first+second+third+fourth jets for jet multiplicites >= 4 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the rapidity of the first jet in the event for jet multiplicities >= 1 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the DeltaR(first jet,second jet) for jet multiplicites >= 2 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the |y(lepton)-y(first jet)| for jet multiplicites >= 2 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the |y(first jet)+y(second jet)| for jet multiplicites >= 2 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the |y(first jet)-y(second jet)| for jet multiplicites >= 2 and jet PT > 30 GeV.

The predicted W+jets cross section as a function of the |phi(first jet)-phi(second jet)| for jet multiplicites >= 2 and jet PT > 30 GeV.

The measured W+jets cross section as a function of the jet multiplicity for jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section ratio as a function of jet multiplicty for jet PT > 20 GeV.

The measured W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 1 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 2 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 3 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 4 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 2 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 3 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 4 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the third jet in the event for jet multiplicities >= 3 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the third jet in the event for jet multiplicities >= 4 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the pT of the fourth jet in the event for jet multiplicities >= 4 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of HT for jet multiplicities >= 1 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of HT for jet multiplicities >= 2 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of HT for jet multiplicities >= 3 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of HT for jet multiplicities >= 4 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the invariant mass of the first+second jets for jet multiplicites >= 2 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the invariant mass of the first+second+third jets for jet multiplicites >= 3 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the invariant mass of the first+second+third+fourth jets for jet multiplicites >= 4 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the rapidity of the first jet in the event for jet multiplicities >= 1 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the DeltaR(first jet,second jet) for jet multiplicites >= 2 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the |y(lepton)-y(first jet)| for jet multiplicites >= 2 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the |y(first jet)+y(second jet)| for jet multiplicites >= 2 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the |y(first jet)-y(second jet)| for jet multiplicites >= 2 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The measured W+jets cross section as a function of the |phi(first jet)-phi(second jet)| for jet multiplicites >= 2 and jet PT > 20 GeV shown for "Born" leptons and for QED corrected "dressed" leptons.

The predicted W+jets cross section as a function of the jet multiplicity for jet PT > 20 GeV.

The predicted W+jets cross section ratio as a function of jet multiplicty for jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 1 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 2 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 3 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the first jet in the event for jet multiplicities >= 4 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 2 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 3 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the second jet in the event for jet multiplicities >= 4 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the third jet in the event for jet multiplicities >= 3 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the third jet in the event for jet multiplicities >= 4 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the pT of the fourth jet in the event for jet multiplicities >= 4 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of HT for jet multiplicities >= 1 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of HT for jet multiplicities >= 2 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of HT for jet multiplicities >= 3 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of HT for jet multiplicities >= 4 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the invariant mass of the first+second jets for jet multiplicites >= 2 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the invariant mass of the first+second+third jets for jet multiplicites >= 3 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the invariant mass of the first+second+third+fourth jets for jet multiplicites >= 4 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the rapidity of the first jet in the event for jet multiplicities >= 1 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the DeltaR(first jet,second jet) for jet multiplicites >= 2 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the |y(lepton)-y(first jet)| for jet multiplicites >= 2 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the |y(first jet)+y(second jet)| for jet multiplicites >= 2 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the |y(first jet)-y(second jet)| for jet multiplicites >= 2 and jet PT > 20 GeV.

The predicted W+jets cross section as a function of the |phi(first jet)-phi(second jet)| for jet multiplicites >= 2 and jet PT > 20 GeV.