Final state radiation correction used in the $\phi_{\eta}^{*}$ cross-section measurement. The first uncertainty is statistical and the second is systematic.

Final state radiation correction used in the $y^{Z}-p_{T}^{Z}$ cross-section measurement. The first uncertainty is statistical and the second is systematic.

Final state radiation correction used in the $y^{Z}-\phi_{\eta}^{*}$ cross-section measurement. The first uncertainty is statistical and the second is systematic.

Correlation matrix of statistical uncertainty for one-dimensional $y^Z$ measurement.

Correlation matrix of statistical uncertainty for one-dimensional $p_{T}^{Z}$ measurement.

Correlation matrix of statistical uncertainty for one-dimensional $\phi_{\eta}^{*}$ measurement.

Correlation matrix of statistical uncertainty for two-dimensional $y^Z-p_{T}^{Z}$ measurement.

Correlation matrix of statistical uncertainty for two-dimensional $y^Z-\phi_{\eta}^{*}$ measurement.

Correlation matrix of efficiency uncertainty for one-dimensional $y^Z$ measurement.

Correlation matrix of efficiency uncertainty for one-dimensional $p_{T}^{Z}$ measurement.

Correlation matrix of efficiency uncertainty for one-dimensional $\phi_{\eta}^{*}$ measurement.

Correlation matrix of efficiency uncertainty for two-dimensional $y^Z-p_{T}^{Z}$ measurement.

Correlation matrix of efficiency uncertainty for two-dimensional $y^Z-\phi_{\eta}^{*}$ measurement.

Measured total $Z$-boson cross-section for different datasets. The first uncertainty is statistical, the second systematic, and the third is due to the luminosity.

Measured single differential cross-sections in interval regions of $y^{Z}$. The first uncertainty is statistical, the second systematic, and the third is due to the luminosity.

Measured single differential cross-sections in interval regions of $p_{T}^{Z}$. The first uncertainty is statistical, the second systematic, and the third is due to the luminosity.

Measured single differential cross-sections in interval regions of $\phi_{\eta}^{*}$. The first uncertainty is statistical, the second systematic, and the third is due to the luminosity.

Measured double differential cross-sections in interval regions of $y^{Z}$ and $p_{T}^{Z}$. The first uncertainty is statistical, the second systematic, and the third is due to the luminosity.

Measured double differential cross-sections in interval regions of $y^{Z}$ and $\phi_{\eta}^{*}$. The first uncertainty is statistical, the second systematic, and the third is due to the luminosity.

Systematic uncertainties in the single differential cross-sections in interval regions of $y^{Z}$, presented in percentage. The contributions from efficiency (Eff), background (BKG), final state radiation (FSR), closure test (Closure), and alignment and calibration (Alignment) are shown.

Systematic uncertainties in the single differential cross-sections in interval regions of $p_{T}^{Z}$, presented in percentage. The contributions from efficiency (Eff), background (BKG), final state radiation (FSR), closure test (Closure), and alignment and calibration (Alignment) are shown.

Systematic uncertainties in the single differential cross-sections in interval regions of $\phi_{\eta}^{*}$, presented in percentage. The contributions from efficiency (Eff), background (BKG), final state radiation (FSR), closure test (Closure), and alignment and calibration (Alignment) are shown.

Systematic uncertainties in the double differential cross-sections in interval regions of $y^{Z}$ and $p_{T}^{Z}$, presented in percentage. The contributions from efficiency (Eff), background (BKG), final state radiation (FSR), closure test (Closure), and alignment and calibration (Alignment) are shown.

Systematic uncertainties in the double differential cross-sections in interval regions of $y^{Z}$ and $\phi_{\eta}^{*}$, presented in percentage. The contributions from efficiency (Eff), background (BKG), final state radiation (FSR), closure test (Closure), and alignment and calibration (Alignment) are shown.

The differential cross section measurement as a function of the transverse momentum of the second leading jet.

The differential cross section measurement as a function of the transverse momentum of the third leading jet.

The differential cross section measurement as a function of the transverse momentum of the fourth leading jet.

The differential cross section measurement as a function of the scalar sum of the transverse momenta of jets (HT) for events with one or more jets.

The differential cross section measurement as a function of the scalar sum of the transverse momenta of jets (HT) for events with two or more jets.

The differential cross section measurement as a function of the scalar sum of the transverse momenta of jets (HT) for events with three or more jets.

The differential cross section measurement as a function of the scalar sum of the transverse momenta of jets (HT) for events with four or more jets.

The differential cross section measurement as a function of the transverse momentum of the dijet system of the two highest pT jets for events with two or more jets.

The differential cross section measurement as a function of the transverse momentum of the dijet system of the two highest pT jets for events with three or more jets.

The differential cross section measurement as a function of the transverse momentum of the dijet system of the two highest pT jets for events with four or more jets.

The differential cross section measurement as a function of the dijet invariant mass of the two highest pT jets for events with two or more jets.

The differential cross section measurement as a function of the dijet invariant mass of the two highest pT jets for events with three or more jets.

The differential cross section measurement as a function of the dijet invariant mass of the two highest pT jets for events with four or more jets.

The differential cross section measurement as a function of the absolute value of the pseudorapidity of the first leading jet.

The differential cross section measurement as a function of the absolute value of the pseudorapidity of the second leading jet.

The differential cross section measurement as a function of the absolute value of the pseudorapidity of the third leading jet.

The differential cross section measurement as a function of the absolute value of the pseudorapidity of the fourth leading jet.

The differential cross section measurement as a function of the rapidity difference between the two highest pT jets for events with two or more jets.

The differential cross section measurement as a function of the rapidity difference between the two highest pT jets for events with three or more jets.

The differential cross section measurement as a function of the rapidity difference between the two highest pT jets for events with four or more jets.

The differential cross section measurement as a function of the rapidity difference between the first and the third highest pT jets for events with three or more jets.

The differential cross section measurement as a function of the rapidity difference between the second and the third highest pT jets for events with three or more jets.

The differential cross section measurement as a function of the rapidity difference between the most forward and the most backward jets for events with two or more jets.

The differential cross section measurement as a function of the rapidity difference between the most forward and the most backward jets for events with three or more jets.

The differential cross section measurement as a function of the rapidity difference between the most forward and the most backward jets for events with four or more jets.

The differential cross section measurement as a function of the azimuthal angle separation between the two highest pT jets for events with two or more jets.

The differential cross section measurement as a function of the azimuthal angle separation between the most forward and the most backward jets for events with two or more jets.

The differential cross section measurement as a function of DeltaR separation between the two highest pT jets for events with two or more jets.

The differential cross section measurement as a function of the azimuthal angle separation between the first leading jet and the muon.

The differential cross section measurement as a function of the azimuthal angle separation between the second leading jet and the muon.

The differential cross section measurement as a function of the azimuthal angle separation between the third leading jet and the muon.

The differential cross section measurement as a function of the azimuthal angle separation between the fourth leading jet and the muon.

Average number of jets as a function of HT for events with one or more jets.

Average number of jets as a function of HT for events with two or more jets.

Average number of jets as a function of the rapidity difference between the two highest pT jets for events with two or more jets.

Average number of jets as a function of the rapidity difference between the most forward and the most backward jets for events with two or more jets.

Differential cross section as a function of the transverse momentum PT of the leading other jet. The first uncertainty is the statistical one, the second uncertainty is the combined systematic uncertainty including luminosity, jet energy scale, sample purity, model dependence and jet energy resolution and trigger efficiency correction.

Differential cross section as a function of the transverse momentum PT of the subleading other jet. The first uncertainty is the statistical one, the second uncertainty is the combined systematic uncertainty including luminosity, jet energy scale, sample purity, model dependence and jet energy resolution and trigger efficiency correction.

Differential cross section as a function of the pseudorapidity ETA of the leading b-jet. The first uncertainty is the statistical one, the second uncertainty is the combined systematic uncertainty including luminosity, jet energy scale, sample purity, model dependence and jet energy resolution and trigger efficiency correction.

Differential cross section as a function of the pseudorapidity ETA of the subleading b-jet. The first uncertainty is the statistical one, the second uncertainty is the combined systematic uncertainty including luminosity, jet energy scale, sample purity, model dependence and jet energy resolution and trigger efficiency correction.

Differential cross section as a function of the pseudorapidity ETA of the leading other jet. The first uncertainty is the statistical one, the second uncertainty is the combined systematic uncertainty including luminosity, jet energy scale, sample purity, model dependence and jet energy resolution and trigger efficiency correction.

Differential cross section as a function of the pseudorapidity ETA of the subleading other jet. The first uncertainty is the statistical one, the second uncertainty is the combined systematic uncertainty including luminosity, jet energy scale, sample purity, model dependence and jet energy resolution and trigger efficiency correction.

Differential cross section as a function of the azimuthal angle DeltaPhi between the two other jets, normalized to the total number of selected events. The first uncertainty is the statistical one, the second uncertainty is the combined systematic uncertainty including luminosity, jet energy scale, sample purity, model dependence and jet energy resolution and trigger efficiency correction.

Differential cross section as a function of the normalized PT balance DELTARELPT between the third and the fourth jet, normalized to the total number of selected events. The first uncertainty is the statistical one, the second uncertainty is the combined systematic uncertainty including luminosity, jet energy scale, sample purity, model dependence and jet energy resolution and trigger efficiency correction.

Differential cross section as a function of the azimuthal angle between the two dijet planes (leading-subleading b- and leading-subleading other jets), normalized to the total number of selected events. The first uncertainty is the statistical one, the second uncertainty is the combined systematic uncertainty including luminosity, jet energy scale, sample purity, model dependence and jet energy resolution and trigger efficiency correction.

Cross section D(SIG)/ET(P=4) as a function of ET(P=4) for X(C=GAMMA,OBS) <= 0.75 .

Cross section D(SIG)/(ETARAP(P=4)+ETARAP(P=5))/2 as a function of (ETARAP(P=4)+ETARAP(P=5))/2 for X(C=GAMMA,OBS) > 0.75 .

Cross section D(SIG)/(ETARAP(P=4)+ETARAP(P=5))/2 as a function of (ETARAP(P=4)+ETARAP(P=5))/2 for X(C=GAMMA,OBS) <= 0.75 .

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) > 0.75 .

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) <= 0.75 .

Cross section D(SIG)/(PHI(P=4)-PHI(P=5))/2 as a function of (PHI(P=4)-PHI(P=5))/2 for X(C=GAMMA,OBS) > 0.75 .

Cross section D(SIG)/(PHI(P=4)-PHI(P=5))/2 as a function of (PHI(P=4)-PHI(P=5))/2 for X(C=GAMMA,OBS) <= 0.75 .

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) > 0.75 for the High X(C=GAMMA,OBS) 1 optimized set.

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) > 0.75 for the High X(C=GAMMA,OBS) 2 optimized set.

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) > 0.75 for the High X(C=GAMMA,OBS) 3 optimized set.

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) > 0.75 for the High X(C=GAMMA,OBS) 4 optimized set.

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) <= 0.75 for the Low X(C=GAMMA,OBS) 1 optimized set.

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) <= 0.75 for the Low X(C=GAMMA,OBS) 2 optimized set.

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) <= 0.75 for the Low X(C=GAMMA,OBS) 3 optimized set.

Cross section D(SIG)/X(C=P,OBS) as a function of X(C=P,OBS) for X(C=GAMMA,OBS) <= 0.75 for the Low X(C=GAMMA,OBS) 4 optimized set.

Cross section D(SIG)/X(C=GAMMA,OBS) as a function of X(C=GAMMA,OBS) .

Two jet cross section D(SIG)/DET(P=5,RF=CM) as a function of ET(P=5,RF=CM).

Two jet cross section D(SIG)/DETARAP(P=4,RF=LAB) as a function of ETARAP(P=4,RF=LAB).

Two jet cross section D(SIG)/DETARAP(P=5,RF=LAB) as a function of ETARAP(P=5,RF=LAB).

Two jet cross section D(SIG)/D(ETARAP(P=4,RF=CM)-ETARAP(P=5,RF=CM)) as a function of ETARAP(P=4,RF=LAB)-ETARAP(P=5,RF=LAB).

Two jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Two jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Two jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Two jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Two jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Two jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Two jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Two jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Two jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Two jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Two jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of ABS(PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Two jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of ABS(PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Two jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of ABS(PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Two jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of ABS(PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Two jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of ABS(PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Two jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Two jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Two jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Two jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Two jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Two jet cross section D2(SIG)/DQ**2/DX as a function of X.

Two jet cross section D2(SIG)/DQ**2/DX as a function of X.

Two jet cross section D2(SIG)/DQ**2/DX as a function of X.

Two jet cross section D2(SIG)/DQ**2/DX as a function of X.

Two jet cross section D2(SIG)/DQ**2/DX as a function of X.

Three jet cross section D(SIG)/DQ**2 as a function of Q**2.

Three jet cross section D(SIG)/DX as a function of X.

Three jet cross section D(SIG)/DET(P=4,RF=CM) as a function of ET(P=4,RF=CM).

Three jet cross section D(SIG)/DET(P=5,RF=CM) as a function of ET(P=5,RF=CM).

Three jet cross section D(SIG)/DET(P=6,RF=CM) as a function of ET(P=6,RF=CM).

Three jet cross section D(SIG)/DETARAP(P=4,RF=LAB) as a function of ETARAP(P=4,RF=LAB).

Three jet cross section D(SIG)/DETARAP(P=5,RF=LAB) as a function of ETARAP(P=5,RF=LAB).

Three jet cross section D(SIG)/DETARAP(P=6,RF=LAB) as a function of ETARAP(P=6,RF=LAB).

Three jet cross section D(SIG)/D(ETARAP(P=4,RF=CM)-ETARAP(P=5,RF=CM)) as a function of ETARAP(P=4,RF=LAB)-ETARAP(P=5,RF=LAB).

Three jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Three jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Three jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Three jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Three jet cross section D2(SIG)/D(ET(P=4,RF=CM)-ET(P=5,RF=CM))/DX as a function of ET(P=4,RF=CM)-ET(P=5,RF=CM).

Three jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Three jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Three jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Three jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Three jet cross section D2(SIG)/D(PT(P=4,RF=CM)-PT(P=5,RF=CM))/DX as a function of PT(P=4,RF=CM)-PT(P=5,RF=CM).

Three jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of (PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Three jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of (PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Three jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of (PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Three jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of (PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Three jet cross section D2(SIG)/DABS((PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM))/DX as a function of (PT(P=4,RF=CM)-PT(P=5,RF=CM))/2*ET(P=4,RF=CM).

Three jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Three jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Three jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Three jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Three jet cross section D2(SIG)/D(PHI(P=4,RF=CM)-PHI(P=5,RF=CM))/DX as a function of PHI(P=4,RF=CM)-PHI(P=5,RF=CM).

Three jet cross section D2(SIG)/DQ**2/DX as a function of X.

Three jet cross section D2(SIG)/DQ**2/DX as a function of X.

Three jet cross section D2(SIG)/DQ**2/DX as a function of X.

Three jet cross section D2(SIG)/DQ**2/DX as a function of X.

Three jet cross section D2(SIG)/DQ**2/DX as a function of X.

Cross section as a function of the jet transverse energy for INCLUSIVE events containing at least one D* meson in different jet pseudorapidity regions.

Cross section as a function of the jet transverse energy for INCLUSIVE events containing at least one D* meson in different jet pseudorapidity regions.

Cross section as a function of the jet pseudorapidity for INCLUSIVE events containing at least one D* meson in different jet transverse energy regions.

Cross section as a function of the jet pseudorapidity for INCLUSIVE events containing at least one D* meson in different jet transverse energy regions.

Cross section as a function of the jet pseudorapidity for INCLUSIVE events containing at least one D* meson in different jet transverse energy regions.

Cross section as a function of the jet transverse energy for D*-TAGGED and UNTAGGED jets in the jet pseudorapidity region -1.5 TO 2.4.

Cross section as a function of the jet pseudorapidity for D*-TAGGED and UNTAGGED jets in 3 regions of jet transverse energy.

Cross section as a function of the jet pseudorapidity for D*-TAGGED and UNTAGGED jets in 3 regions of jet transverse energy.

Cross section as a function of the jet pseudorapidity for D*-TAGGED and UNTAGGED jets in 3 regions of jet transverse energy.

Cross section as a function of the jet transverse energy in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet transverse energy in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet transverse energy in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet pseudorapidity in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet pseudorapidity in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet pseudorapidity in 3 regions of transverse momentum of the D*.

Cross section as a function of XOBS(C=GAMMA,D*,JET) where the jet here is the UNTAGGED jet with the lightest ET.

The dijet cross section as a function of XOBS(C=GAMMA) for events containing at least one D* meson.

The dijet cross section as a function of the PHI angle difference in JET1 and JET2 for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the PHI angle difference in JET1 and JET2 for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the PHI angle difference in JET1 and JET2 for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the 2-jet transverse momentum for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the 2-jet transverse momentum for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the 2-jet transverse momentum for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the the 2-jet mass for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the the 2-jet mass for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the the 2-jet mass for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

Distribution for the maxPT jet above 180 GeV.

Differential cross section as a function of the ratio of the virtualities of the two photons.

Differential cross section as a function of the acolinearity angle PHI between the scattered electrons.

Differential cross section as a function of the acolinearity angle DEL(PHI) between the scattered electrons.

Differential cross section as a function of W of the hadronic system.

Differential cross section as a function of the Bjorken X.

Differential cross section as a function of the DIS Y variable.

Differential cross section as a function of LOG(S/S0).

The folded normalised differential cross section as a function of azimuthalangle for inclusive jet production in the Breit frame.

Acceptance corrected COS(THETA(XYZ=SH)) distribution for exclusive J/PSI photoproduction muon decay data. THETA(XYZ=SH) is the polar angle of the positively charged lepton in the helicity frame.

Acceptance corrected COS(THETA(XYZ=SH)) distribution for exclusive J/PSI photoproduction electron decay data. THETA(XYZ=SH) is the polar angle of the positively charged lepton in the helicity frame.

Acceptance corrected PHI(XYZ=SH)) distribution for exclusive J/PSI photoproduction muon decay data. PHI(XYZ=SH) is the azimuthal angle of the positively charged lepton in the helicity frame.

Acceptance corrected PHI(XYZ=SH)) distribution for exclusive J/PSI photoproduction electron decay data. PHI(XYZ=SH) is the azimuthal angle of the positively charged lepton in the helicity frame.

Spin density matrix elements from fits to the angular distributions.

Differential DSIG/DT distribution in various W bins for data from J/PSI muon decay.

Differential DSIG/DT distribution in various W bins for data from J/PSI electron decay.

Slope of the Pomeron trajectory obtained from fit to the DSIG/DT distribution of the form W**(4*SLOPE-1) from the J/PSI muon decay data.

Slope of the Pomeron trajectory obtained from fit to the DSIG/DT distribution of the form W**(4*SLOPE-1) from the J/PSI electron decay data.