The cross section measurement as a function of the inclusive jet multiplicity, for jet multiplicities of up to 7.

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

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

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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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.

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 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 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 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.

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.

Fully corrected average charged particle scalar Sum(pT) per unit of pseudorapidity and per radian as a function of the leading track-jet transverse momentum for proton-proton collisions at a centre-of-mass energy of 2.76 TeV in the TransMAX region.

Fully corrected average charged particle multiplicity per unit of pseudorapidity and per radian as a function of the leading track-jet transverse momentum for proton-proton collisions at a centre-of-mass energy of 2.76 TeV in the TransMIN region.

Fully corrected average charged particle scalar Sum(pT) per unit of pseudorapidity and per radian as a function of the leading track-jet transverse momentum for proton-proton collisions at a centre-of-mass energy of 2.76 TeV in the TransMIN region.

Fully corrected average charged particle multiplicity per unit of pseudorapidity and per radian as a function of the leading track-jet transverse momentum for proton-proton collisions at a centre-of-mass energy of 2.76 TeV in the TransDIF region.

Fully corrected average charged particle scalar Sum(pT) per unit of pseudorapidity and per radian as a function of the leading track-jet transverse momentum for proton-proton collisions at a centre-of-mass energy of 2.76 TeV in the TransDIF region.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted.

pi+ multiplicities from HERMES, Target: H, VM subtracted, Not VM subtracted.

pi- multiplicities from HERMES, Target: H, VM subtracted, Not VM subtracted.

K+ multiplicities from HERMES, Target: H, VM subtracted, Not VM subtracted.

K- multiplicities from HERMES, Target: H, VM subtracted, Not VM subtracted.

pi+ target asymmetries from HERMES, VM subtracted.

pi- target asymmetries from HERMES, VM subtracted.

K+ target asymmetries from HERMES, VM subtracted.

K- target asymmetries from HERMES, VM subtracted.

pi+ target asymmetries from HERMES, pi- target asymmetries from HERMES, VM subtracted, Z in the range 0.2-0.3.

pi+ target asymmetries from HERMES, pi- target asymmetries from HERMES, VM subtracted, Z in the range 0.3-0.4.

pi+ target asymmetries from HERMES, pi- target asymmetries from HERMES, VM subtracted, Z in the range 0.4-0.6.

pi+ target asymmetries from HERMES, pi- target asymmetries from HERMES, VM subtracted, Z in the range 0.6-0.8.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

pi+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

pi- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

K+ multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.2-0.3.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.3-0.4.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.4-0.6.

K- multiplicities from HERMES, Target: H, Target: D, VM subtracted, Z in the range 0.6-0.8.

The measured differential jet shape $\rho(r)$ for jets with 40 GeV $< p_{\mathrm{T}} <$ 50 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 50 GeV $< p_{\mathrm{T}} <$ 60 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 60 GeV $< p_{\mathrm{T}} <$ 70 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 70 GeV $< p_{\mathrm{T}} <$ 80 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 80 GeV $< p_{\mathrm{T}} <$ 90 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 90 GeV $< p_{\mathrm{T}} <$ 100 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 100 GeV $< p_{\mathrm{T}} <$ 110 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 110 GeV $< p_{\mathrm{T}} <$ 125 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 125 GeV $< p_{\mathrm{T}} <$ 140 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 140 GeV $< p_{\mathrm{T}} <$ 160 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 160 GeV $< p_{\mathrm{T}} <$ 180 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 180 GeV $< p_{\mathrm{T}} <$ 200 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 200 GeV $< p_{\mathrm{T}} <$ 225 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 225 GeV $< p_{\mathrm{T}} <$ 250 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 250 GeV $< p_{\mathrm{T}} <$ 300 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 300 GeV $< p_{\mathrm{T}} <$ 400 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 400 GeV $< p_{\mathrm{T}} <$ 500 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 500 GeV $< p_{\mathrm{T}} <$ 600 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 600 GeV $< p_{\mathrm{T}} <$ 1000 GeV and 0 <|y|< 0.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 20 GeV $< p_{\mathrm{T}} <$ 25 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 25 GeV $< p_{\mathrm{T}} <$ 30 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 30 GeV $< p_{\mathrm{T}} <$ 40 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 40 GeV $< p_{\mathrm{T}} <$ 50 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 50 GeV $< p_{\mathrm{T}} <$ 60 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 60 GeV $< p_{\mathrm{T}} <$ 70 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 70 GeV $< p_{\mathrm{T}} <$ 80 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 80 GeV $< p_{\mathrm{T}} <$ 90 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 90 GeV $< p_{\mathrm{T}} <$ 100 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 100 GeV $< p_{\mathrm{T}} <$ 110 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 110 GeV $< p_{\mathrm{T}} <$ 125 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 125 GeV $< p_{\mathrm{T}} <$ 140 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 140 GeV $< p_{\mathrm{T}} <$ 160 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 160 GeV $< p_{\mathrm{T}} <$ 180 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 180 GeV $< p_{\mathrm{T}} <$ 200 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 200 GeV $< p_{\mathrm{T}} <$ 225 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 225 GeV $< p_{\mathrm{T}} <$ 250 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 250 GeV $< p_{\mathrm{T}} <$ 300 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 300 GeV $< p_{\mathrm{T}} <$ 400 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 400 GeV $< p_{\mathrm{T}} <$ 500 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 500 GeV $< p_{\mathrm{T}} <$ 600 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 600 GeV $< p_{\mathrm{T}} <$ 1000 GeV and 0.5 <|y|< 1.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 20 GeV $< p_{\mathrm{T}} <$ 25 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 25 GeV $< p_{\mathrm{T}} <$ 30 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 30 GeV $< p_{\mathrm{T}} <$ 40 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 40 GeV $< p_{\mathrm{T}} <$ 50 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 50 GeV $< p_{\mathrm{T}} <$ 60 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 60 GeV $< p_{\mathrm{T}} <$ 70 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 70 GeV $< p_{\mathrm{T}} <$ 80 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 80 GeV $< p_{\mathrm{T}} <$ 90 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 90 GeV $< p_{\mathrm{T}} <$ 100 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 100 GeV $< p_{\mathrm{T}} <$ 110 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 110 GeV $< p_{\mathrm{T}} <$ 125 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 125 GeV $< p_{\mathrm{T}} <$ 140 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 140 GeV $< p_{\mathrm{T}} <$ 160 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 160 GeV $< p_{\mathrm{T}} <$ 180 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 180 GeV $< p_{\mathrm{T}} <$ 200 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 200 GeV $< p_{\mathrm{T}} <$ 225 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 225 GeV $< p_{\mathrm{T}} <$ 250 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 250 GeV $< p_{\mathrm{T}} <$ 300 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 300 GeV $< p_{\mathrm{T}} <$ 400 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 400 GeV $< p_{\mathrm{T}} <$ 500 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 500 GeV $< p_{\mathrm{T}} <$ 600 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 600 GeV $< p_{\mathrm{T}} <$ 1000 GeV and 1.0 <|y|< 1.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 20 GeV $< p_{\mathrm{T}} <$ 25 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 25 GeV $< p_{\mathrm{T}} <$ 30 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 30 GeV $< p_{\mathrm{T}} <$ 40 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 40 GeV $< p_{\mathrm{T}} <$ 50 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 50 GeV $< p_{\mathrm{T}} <$ 60 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 60 GeV $< p_{\mathrm{T}} <$ 70 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 70 GeV $< p_{\mathrm{T}} <$ 80 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 80 GeV $< p_{\mathrm{T}} <$ 90 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 90 GeV $< p_{\mathrm{T}} <$ 100 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 100 GeV $< p_{\mathrm{T}} <$ 110 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 110 GeV $< p_{\mathrm{T}} <$ 125 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 125 GeV $< p_{\mathrm{T}} <$ 140 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 140 GeV $< p_{\mathrm{T}} <$ 160 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 160 GeV $< p_{\mathrm{T}} <$ 180 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 180 GeV $< p_{\mathrm{T}} <$ 200 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 200 GeV $< p_{\mathrm{T}} <$ 225 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 225 GeV $< p_{\mathrm{T}} <$ 250 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 250 GeV $< p_{\mathrm{T}} <$ 300 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 300 GeV $< p_{\mathrm{T}} <$ 400 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 400 GeV $< p_{\mathrm{T}} <$ 500 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 500 GeV $< p_{\mathrm{T}} <$ 600 GeV and 1.5 <|y|< 2.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 20 GeV $< p_{\mathrm{T}} <$ 25 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 25 GeV $< p_{\mathrm{T}} <$ 30 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 30 GeV $< p_{\mathrm{T}} <$ 40 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 40 GeV $< p_{\mathrm{T}} <$ 50 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 50 GeV $< p_{\mathrm{T}} <$ 60 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 60 GeV $< p_{\mathrm{T}} <$ 70 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 70 GeV $< p_{\mathrm{T}} <$ 80 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 80 GeV $< p_{\mathrm{T}} <$ 90 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 90 GeV $< p_{\mathrm{T}} <$ 100 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 100 GeV $< p_{\mathrm{T}} <$ 110 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 110 GeV $< p_{\mathrm{T}} <$ 125 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 125 GeV $< p_{\mathrm{T}} <$ 140 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 140 GeV $< p_{\mathrm{T}} <$ 160 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 160 GeV $< p_{\mathrm{T}} <$ 180 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 180 GeV $< p_{\mathrm{T}} <$ 200 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 200 GeV $< p_{\mathrm{T}} <$ 225 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 225 GeV $< p_{\mathrm{T}} <$ 250 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 250 GeV $< p_{\mathrm{T}} <$ 300 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 300 GeV $< p_{\mathrm{T}} <$ 400 GeV and 2.0 <|y|< 2.5. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 20 GeV $< p_{\mathrm{T}} <$ 25 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 25 GeV $< p_{\mathrm{T}} <$ 30 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 30 GeV $< p_{\mathrm{T}} <$ 40 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 40 GeV $< p_{\mathrm{T}} <$ 50 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 50 GeV $< p_{\mathrm{T}} <$ 60 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 60 GeV $< p_{\mathrm{T}} <$ 70 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 70 GeV $< p_{\mathrm{T}} <$ 80 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 80 GeV $< p_{\mathrm{T}} <$ 90 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 90 GeV $< p_{\mathrm{T}} <$ 100 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 100 GeV $< p_{\mathrm{T}} <$ 110 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 110 GeV $< p_{\mathrm{T}} <$ 125 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 125 GeV $< p_{\mathrm{T}} <$ 140 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 140 GeV $< p_{\mathrm{T}} <$ 160 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 160 GeV $< p_{\mathrm{T}} <$ 180 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 180 GeV $< p_{\mathrm{T}} <$ 200 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 200 GeV $< p_{\mathrm{T}} <$ 225 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 225 GeV $< p_{\mathrm{T}} <$ 250 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 250 GeV $< p_{\mathrm{T}} <$ 300 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The measured differential jet shape $\rho(r)$ for jets with 300 GeV $< p_{\mathrm{T}} <$ 400 GeV and 2.5 <|y|< 3.0. The CF in the table refers to unfolding correction factor from {\sc pythia6} Tune Z2. The systematic uncertainties from different sources, jet energy scale (JES), unfolding, and single particle response (SPR), are also presented.

The dependence of $\langle N_\mathrm{ch} \rangle$ on the transverse momentum of jets in two different rapidity regions, $|y| < 1$ and $1 < |y| < 2$.

The dependence of $\langle \delta R^2 \rangle$ on the transverse momentum of jets in two different rapidity regions, $|y| < 1$ and $ 1 < |y| < 2 $.

The dependence of $\langle\delta \eta^2\rangle/\langle\delta \phi^2\rangle$ on the transverse momentum for jets with $|y| < 1$.

Distribution of the total energy outside the reconstructed jets for the completed data samples. Also tabulated is the estimated background.

Distribution of the total energy outside the reconstructed jets for the 'Dir' domain. Also tabulated is the estimated background.

Distribution of the total energy outside the reconstructed jets for the 'SR' domain. Also tabulated is the estimated background.

Distribution of the total energy outside the reconstructed jets for the 'DR' domain. Also tabulated is the estimated background.

Observed distribution of the charged particle multiplicity.

Observed distribution of the charged particle invariant mass.

Observed distribution of the mean of X(C=GAMMA-PLUS) and X(GAMMA-MINUS).

Observed mean number of particles in the reconstructed jets.

PI+ multiplicty ratio (Helium/Deuterium) as a function of Z.

K+ multiplicty ratio (Helium/Deuterium) as a function of Z.

P multiplicty ratio (Helium/Deuterium) as a function of Z.

PI+ multiplicty ratio (Helium/Deuterium) as a function of Q**2.

K+ multiplicty ratio (Helium/Deuterium) as a function of Q**2.

P multiplicty ratio (Helium/Deuterium) as a function of Q**2.

PI+ multiplicty ratio (Neon/Deuterium) as a function of NU.

K+ multiplicty ratio (Neon/Deuterium) as a function of NU.

P multiplicty ratio (Neon/Deuterium) as a function of NU.

PI+ multiplicty ratio (Neon/Deuterium) as a function of Z.

K+ multiplicty ratio (Neon/Deuterium) as a function of Z.

P multiplicty ratio (Neon/Deuterium) as a function of Z.

PI+ multiplicty ratio (Neon/Deuterium) as a function of Q**2.

K+ multiplicty ratio (Neon/Deuterium) as a function of Q**2.

P multiplicty ratio (Neon/Deuterium) as a function of Q**2.

PI+ multiplicty ratio (Krypton/Deuterium) as a function of NU.

K+ multiplicty ratio (Krypton/Deuterium) as a function of NU.

P multiplicty ratio (Krypton/Deuterium) as a function of NU.

PI+ multiplicty ratio (Krypton/Deuterium) as a function of Z.

K+ multiplicty ratio (Krypton/Deuterium) as a function of Z.

P multiplicty ratio (Krypton/Deuterium) as a function of Z.

PI+ multiplicty ratio (Krypton/Deuterium) as a function of Q**2.

K+ multiplicty ratio (Krypton/Deuterium) as a function of Q**2.

P multiplicty ratio (Krypton/Deuterium) as a function of Q**2.

PI+ multiplicty ratio (Xenon/Deuterium) as a function of NU.

K+ multiplicty ratio (Xenon/Deuterium) as a function of NU.

P multiplicty ratio (Xenon/Deuterium) as a function of NU.

PI+ multiplicty ratio (Xenon/Deuterium) as a function of Z.

K+ multiplicty ratio (Xenon/Deuterium) as a function of Z.

P multiplicty ratio (Xenon/Deuterium) as a function of Z.

PI+ multiplicty ratio (Xenon/Deuterium) as a function of Q**2.

K+ multiplicty ratio (Xenon/Deuterium) as a function of Q**2.

P multiplicty ratio (Xenon/Deuterium) as a function of Q**2.

PI- multiplicity ratio (Helium/Deuterium) as a function of NU.

K- multiplicity ratio (Helium/Deuterium) as a function of NU.

PBAR multiplicity ratio (Helium/Deuterium) as a function of NU.

PI- multiplicity ratio (Helium/Deuterium) as a function of Z.

K- multiplicity ratio (Helium/Deuterium) as a function of Z.

PBAR multiplicity ratio (Helium/Deuterium) as a function of Z.

PI- multiplicity ratio (Helium/Deuterium) as a function of Q**2.

K- multiplicity ratio (Helium/Deuterium) as a function of Q**2.

PBAR multiplicity ratio (Helium/Deuterium) as a function of Q**2.

PI- multiplicity ratio (Neon/Deuterium) as a function of NU.

K- multiplicity ratio (Neon/Deuterium) as a function of NU.

PBAR multiplicity ratio (Neon/Deuterium) as a function of NU.

PI- multiplicity ratio (Neon/Deuterium) as a function of Z.

K- multiplicity ratio (Neon/Deuterium) as a function of Z.

PBAR multiplicity ratio (Neon/Deuterium) as a function of Z.

PI- multiplicity ratio (Neon/Deuterium) as a function of Q**2.

K- multiplicity ratio (Neon/Deuterium) as a function of Q**2.

PBAR multiplicity ratio (Neon/Deuterium) as a function of Q**2.

PI- multiplicity ratio (Krypton/Deuterium) as a function of NU.

K- multiplicity ratio (Krypton/Deuterium) as a function of NU.

PBAR multiplicity ratio (Krypton/Deuterium) as a function of NU.

PI- multiplicity ratio (Krypton/Deuterium) as a function of Z.

K- multiplicity ratio (Krypton/Deuterium) as a function of Z.

PBAR multiplicity ratio (Krypton/Deuterium) as a function of Z.

PI- multiplicity ratio (Krypton/Deuterium) as a function of Q**2.

K- multiplicity ratio (Krypton/Deuterium) as a function of Q**2.

PBAR multiplicity ratio (Krypton/Deuterium) as a function of Q**2.

PI- multiplicity ratio (Xenon/Deuterium) as a function of NU.

K- multiplicity ratio (Xenon/Deuterium) as a function of NU.

PBAR multiplicity ratio (Xenon/Deuterium) as a function of NU.

PI- multiplicity ratio (Xenon/Deuterium) as a function of Z.

K- multiplicity ratio (Xenon/Deuterium) as a function of Z.

PBAR multiplicity ratio (Xenon/Deuterium) as a function of Z.

PI- multiplicity ratio (Xenon/Deuterium) as a function of Q**2.

K- multiplicity ratio (Xenon/Deuterium) as a function of Q**2.

PBAR multiplicity ratio (Xenon/Deuterium) as a function of Q**2.

PI+ multiplicity ratio (Helium/Deuterium) as a function of PT**2.

K+ multiplicity ratio (Helium/Deuterium) as a function of PT**2.

P multiplicity ratio (Helium/Deuterium) as a function of PT**2.

PI- multiplicity ratio (Helium/Deuterium) as a function of PT**2.

K- multiplicity ratio (Helium/Deuterium) as a function of PT**2.

PBAR multiplicity ratio (Helium/Deuterium) as a function of PT**2.

PI+ multiplicity ratio (Neon/Deuterium) as a function of PT**2.

K+ multiplicity ratio (Neon/Deuterium) as a function of PT**2.

P multiplicity ratio (Neon/Deuterium) as a function of PT**2.

PI- multiplicity ratio (Neon/Deuterium) as a function of PT**2.

K- multiplicity ratio (Neon/Deuterium) as a function of PT**2.

PBAR multiplicity ratio (Neon/Deuterium) as a function of PT**2.

PI+ multiplicity ratio (Krypton/Deuterium) as a function of PT**2.

K+ multiplicity ratio (Krypton/Deuterium) as a function of PT**2.

P multiplicity ratio (Krypton/Deuterium) as a function of PT**2.

PI- multiplicity ratio (Krypton/Deuterium) as a function of PT**2.

K- multiplicity ratio (Krypton/Deuterium) as a function of PT**2.

PBAR multiplicity ratio (Krypton/Deuterium) as a function of PT**2.

PI+ multiplicity ratio (Xenon/Deuterium) as a function of PT**2.

K+ multiplicity ratio (Xenon/Deuterium) as a function of PT**2.

P multiplicity ratio (Xenon/Deuterium) as a function of PT**2.

PI- multiplicity ratio (Xenon/Deuterium) as a function of PT**2.

K- multiplicity ratio (Xenon/Deuterium) as a function of PT**2.

PBAR multiplicity ratio (Xenon/Deuterium) as a function of PT**2.

PI0 multiplicity ratio (Helium/Deuterium) as a function of NU.

PI0 multiplicity ratio (Helium/Deuterium) as a function of Z.

PI0 multiplicity ratio (Helium/Deuterium) as a function of Q**2.

PI0 multiplicity ratio (Helium/Deuterium) as a function of PT**2.

PI0 multiplicity ratio (Neon/Deuterium) as a function of NU.

PI0 multiplicity ratio (Neon/Deuterium) as a function of Z.

PI0 multiplicity ratio (Neon/Deuterium) as a function of Q**2.

PI0 multiplicity ratio (Neon/Deuterium) as a function of PT**2.

PI0 multiplicity ratio (Krypton/Deuterium) as a function of NU.

PI0 multiplicity ratio (Krypton/Deuterium) as a function of Z.

PI0 multiplicity ratio (Krypton/Deuterium) as a function of Q**2.

PI0 multiplicity ratio (Krypton/Deuterium) as a function of PT**2.

PI0 multiplicity ratio (Xenon/Deuterium) as a function of NU.

PI0 multiplicity ratio (Xenon/Deuterium) as a function of Z.

PI0 multiplicity ratio (Xenon/Deuterium) as a function of Q**2.

PI0 multiplicity ratio (Xenon/Deuterium) as a function of PT**2.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of NU for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of NU for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of NU for Z > 0.7.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of Q**2 for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of Q**2 for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of Q**2 for Z > 0.7.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of PT**2 for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of PT**2 for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of PT**2 for Z > 0.7.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of NU for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of NU for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of NU for Z > 0.7.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of Q**2 for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of Q**2 for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of Q**2 for Z > 0.7.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of PT**2 for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of PT**2 for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of PT**2 for Z > 0.7.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of NU for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of NU for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of NU for Z > 0.7.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of Q**2 for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of Q**2 for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of Q**2 for Z > 0.7.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of PT**2 for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of PT**2 for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of PT**2 for Z > 0.7.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of NU for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of NU for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of NU for Z > 0.7.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of Q**2 for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of Q**2 for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of Q**2 for Z > 0.7.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of PT**2 for Z 0.2 TO 0.4.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of PT**2 for Z 0.4 TO 0.7.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of PT**2 for Z > 0.7.

Charged pion multiplicity ratio(Helium/Deuterium) as a function of Z for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Helium/Deuterium) as a function of Z for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Helium/Deuterium) as a function of Z for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Helium/Deuterium) as a function of Q**2 for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Helium/Deuterium) as a function of Q**2 for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Helium/Deuterium) as a function of Q**2 for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Helium/Deuterium) as a function of PT**2 for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Helium/Deuterium) as a function of PT**2 for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Helium/Deuterium) as a function of PT**2 for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Neon/Deuterium) as a function of Z for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Neon/Deuterium) as a function of Z for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Neon/Deuterium) as a function of Z for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Neon/Deuterium) as a function of Q**2 for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Neon/Deuterium) as a function of Q**2 for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Neon/Deuterium) as a function of Q**2 for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Neon/Deuterium) as a function of PT**2 for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Neon/Deuterium) as a function of PT**2 for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Neon/Deuterium) as a function of PT**2 for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Krypton/Deuterium) as a function of Z for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Krypton/Deuterium) as a function of Z for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Krypton/Deuterium) as a function of Z for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Krypton/Deuterium) as a function of Q**2 for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Krypton/Deuterium) as a function of Q**2 for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Krypton/Deuterium) as a function of Q**2 for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Krypton/Deuterium) as a function of PT**2 for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Krypton/Deuterium) as a function of PT**2 for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Krypton/Deuterium) as a function of PT**2 for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Xenon/Deuterium) as a function of Z for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Xenon/Deuterium) as a function of Z for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Xenon/Deuterium) as a function of Z for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Xenon/Deuterium) as a function of Q**2 for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Xenon/Deuterium) as a function of Q**2 for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Xenon/Deuterium) as a function of Q**2 for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio(Xenon/Deuterium) as a function of PT**2 for NU 6 TO 12 GeV.

Charged pion multiplicity ratio(Xenon/Deuterium) as a function of PT**2 for NU 12 TO 17 GeV.

Charged pion multiplicity ratio(Xenon/Deuterium) as a function of PT**2 for NU 17 TO 23.5 GeV.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of NU for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of NU for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of Z for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of Z for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of Q**2 for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of Q**2 for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of NU for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of NU for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of Z for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of Z for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of Q**2 for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of Q**2 for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of NU for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of NU for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of Z for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of Z for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of Q**2 for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of Q**2 for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of NU for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of NU for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of Z for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of Z for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of Q**2 for PT**2 < 0.7 GeV**2.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of Q**2 for PT**2 > 0.7 GeV**2.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 20 TO 23.5 GeV.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 17 TO 20 GeV.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 14 TO 17 GeV.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 11 TO 14 GeV.

Charged pion multiplicity ratio (Helium/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 6 TO 11 GeV.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 20 TO 23.5 GeV.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 17 TO 20 GeV.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 14 TO 17 GeV.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 11 TO 14 GeV.

Charged pion multiplicity ratio (Neon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 6 TO 11 GeV.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 20 TO 23.5 GeV.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 17 TO 20 GeV.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 14 TO 17 GeV.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 11 TO 14 GeV.

Charged pion multiplicity ratio (Krypton/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 6 TO 11 GeV.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 20 TO 23.5 GeV.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 17 TO 20 GeV.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 14 TO 17 GeV.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 11 TO 14 GeV.

Charged pion multiplicity ratio (Xenon/Deuterium) as a function of the formation Length Lc (see text of paper). for NU 6 TO 11 GeV.

The measured pion (neutral+charged) multiplicity as a function of Q**2 for four z regions.

Average multiplicities of identified hadrons produced in fully hadronic (4Q) and semi-leptonic (2Q) W decays at a centre-of-mass energy of 189 GeV.

Corrected momentum distributions of charged particles for 4Q and 2Q events at a centre-of-mass energy 189 GeV.

The difference (4Q-2*2Q) between the fully hadronic and semileptonic momentum distributions at a centre-of-mass energy 189 GeV.

Corrected momentum distributions of charged particles for 4Q and 2Q events at a centre-of-mass energy 183 GeV.

The difference (4Q-2*2Q) between the fully hadronic and semileptonic momentum distributions at a centre-of-mass energy 183 GeV.

Corrected -LN(1/X) distributions for 4Q and 2Q events, and their difference4Q-2*2Q for a centre-of-mass energy of 189 GeV.

Corrected -LN(1/X) distributions for 4Q and 2Q events, and their difference4Q-2*2Q for a centre-of-mass energy of 183 GeV.

Corrected PT distributions for 4Q and 2Q events, and their difference 4Q-2*2Q for a centre-of-mass energy of 189 GeV.

Corrected PT distributions for 4Q and 2Q events, and their difference 4Q-2*2Q for a centre-of-mass energy of 183 GeV.

LN(1/X) distributions for charged particles and identified hadrons producedin hadronic QQBAR events at a centre-of-mass energy of 189 GeV.

LN(1/X) distributions for charged particles and identified hadrons producedin fully hadronic two W decay events at a centre-of-mass energy of 189 GeV.

LN(1/X) distributions for charged particles and identified hadrons producedin semi-leptonic two W decay events at a centre-of-mass energy of 189 GeV.

LN(1/X) distributions for neutral kaons and lambda particles produced in hadronic QQBAR events at a centre-of-mass energies of 183 and 189 GeV.

Jet flavor tagging is used. (C=DUSCB), (C=DUSC), (C=UDS) mean quark-jet flavors. CONST(C=GLUON/JET) is the ratio gluon/jet for all charged particles. 'Y' events, mirror symmetric events, the angle between the most energetic jet and other two jets is 150 +- 15 deg.

Jet flavor tagging is used. (C=DUSCB), (C=DUSC), (C=UDS) mean quark-jet flavors. CONST(C=GLUON/JET) is the ratio gluon/jet for all charged particles. 'Mercedes' events, three-fold symmetric events, the angle between three jets is 120 +- 15 deg.

Jet flavor tagging is used. (C=DUSCB), (C=DUSC), (C=UDS) mean quark-jet flavors. CONST(C=GLUON/JET) is the ratio gluon/jet for all charged particles. 'Mercedes' events, three-fold symmetric events, the angle between three jets is 120 +- 15 deg.

Jet flavor tagging is used. (C=DUSCB), (C=DUSC), (C=UDS) mean quark-jet flavors. CONST(C=GLUON/JET) is the ratio gluon/jet for all charged particles. 'Mercedes' events, three-fold symmetric events, the angle between three jets is 120 +- 15 deg.

Jet flavor tagging is used. (C=DUSCB), (C=DUSC), (C=UDS) mean quark-jet flavors. CONST(C=GLUON/JET) is the ratio gluon/jet for all charged particles. 'Mercedes' events, three-fold symmetric events, the angle between three jets is 120 +- 15 deg.

Jet flavor tagging is used. 'Y' events, mirror symmetric events, the angle between the most energetic jet and other two jets is 150 +- 15 deg.. CONST(NAME=XISTAR) is maximum of log(P(C=CHARGED)/P(C=JET)) distribution.

Jet flavor tagging is used. 'Mercedes' events, three-fold symmetric events, the angle between three jets is 120 +- 15 deg.. CONST(NAME=XISTAR) is maximum of log(P(C=CHARGED)/P(C=JET)) distribution.

No description provided.