The results of fits of the two-particle double-ratio correlation function $R_{2} (Q)$ for $\sqrt{s} = 0.9\ TeV$ events with the unlike-charge reference sample for various multiplicity intervals $n_{ch}$ for the exponential parametrization $\Omega^{(E)}$. The uncertainties for parameters $\lambda$ and $R$ are square root from the quadratic sum of statistical and systematic errors. Where only one error is shown for parameters $C_{0}$ and $\epsilon$, this represents the statistical uncertainty only.

The results of fits of the two-particle double-ratio correlation function $R_{2} (Q)$ for $\sqrt{s} = 7\ TeV$ events with the unlike-charge reference sample for various multiplicity intervals $n_{ch}$ for the exponential parametrization $\Omega^{(E)}$. The uncertainties for parameters $\lambda$ and $R$ are square root from the quadratic sum of statistical and systematic errors. The statistical uncertainties at $7\ TeV$ were corrected on the $\sqrt{\chi^{2}/ndf}$ and they more smaller than systematic uncertainties. Where only one error is shown for parameters $C_{0}$ and $\epsilon$, this represents the statistical uncertainty only.

The results of fits of the two-particle double-ratio correlation function $R_{2} (Q)$ for $\sqrt{s} = 7\ TeV\ HM$ events with the unlike-charge reference sample for various multiplicity intervals $n_{ch}$ for the exponential parametrization $\Omega^{(E)}$. The uncertainties for parameters $\lambda$ and $R$ are square root from the quadratic sum of statistical and systematic errors. Where only one error is shown for parameters $C_{0}$ and $\epsilon$, this represents the statistical uncertainty only.

The results of fits of the two-particle double-ratio correlation function $R_{2} (Q)$ for $\sqrt{s} = 0.9\ TeV$ ($n_{ch} \ge 2$) events with the unlike-charge reference sample for various $k_{T}$ intervals for the exponential parametrization $\Omega^{(E)}$. The uncertainties for parameters $\lambda$ and $R$ are square root from the quadratic sum of statistical and systematic errors. The statistical uncertainties were corrected on the $\sqrt{\chi^{2}/ndf}$ when $\chi^{2}/ndf > 1$. Where only one error is shown for parameters $C_{0}$ and $\epsilon$, this represents the statistical uncertainty only.

The results of fits of the two-particle double-ratio correlation function $R_{2} (Q)$ for $\sqrt{s} = 7\ TeV$ ($n_{ch} \ge 2$) events with the unlike-charge reference sample for various $k_{T}$ intervals for the exponential parametrization $\Omega^{(E)}$. The uncertainties for parameters $\lambda$ and $R$ are square root from the quadratic sum of statistical and systematic errors. Where only one error is shown for parameters $C_{0}$ and $\epsilon$ , this represents the statistical uncertainty only. The statistical uncertainties were corrected on the $\sqrt{\chi^{2}/ndf}$ when $\chi^{2}/ndf > 1$. The statistical uncertainties at $7\ TeV$ more smaller than systematic uncertainties.

The results of fits of the two-particle double-ratio correlation function $R_{2} (Q)$ for $\sqrt{s} = 7\ TeV\ HM$ ($n_{ch} \ge 150$) events with the unlike-charge reference sample for various $k_{T}$ intervals for the exponential parametrization $\Omega^{(E)}$. The uncertainties for parameters $\lambda$ and $R$ are square root from the quadratic sum of statistical and systematic errors. The statistical uncertainties were corrected on the $\sqrt{\chi^{2}/ndf}$ when $\chi^{2}/ndf > 1$.Where only one error is shown for parameters $C_{0}$ and $\epsilon$, this represents the statistical uncertainty only.

The results of fits of the two-particle double-ratio correlation function $R_{2} (Q)$ for $\sqrt{s} = 7\ TeV$ events with the unlike-charge reference sample for various $k_{T}$ intervals of different multiplicity regions $n_{ch}$ for the exponential parametrization $\Omega^{(E)}$. The statistical uncertainties were corrected on the $\sqrt{\chi^{2}/ndf}$ when $\chi^{2}/ndf > 1$. The statistical uncertainties smaller than systematic uncertainties. The uncertainties for parameters $\lambda$ and $R$ are square root from the quadratic sum of statistical and systematic errors. Where only one error is shown for parameters $C_{0}$ and $\epsilon$, this represents the statistical uncertainty only.

The $Q$ distribution measured at $0.9\ TeV$ for unlike-sign pairs for $p_{T} > 100\ MeV$ and $|\eta|<2.5$, renormalized to the total number of charged-particle pairs. The error bars represents the statistical uncertainties.

The $Q$ distribution measured at $0.9\ TeV$ for like-sign pairs for $p_{T} > 100\ MeV$ and $|\eta|<2.5$, renormalized to the total number of charged-particle pairs. The error bars represents the statistical uncertainties.

The $Q$ distribution measured at $7\ TeV$ for unlike-sign pairs for $p_{T} > 100\ MeV$ and $|\eta|<2.5$, renormalized to the total number of charged-particle pairs. The error bars represents the statistical uncertainties.

The $Q$ distribution measured at $7\ TeV$ for like-sign pairs for $p_{T} > 100\ MeV$ and $|\eta|<2.5$, renormalized to the total number of charged-particle pairs. The error bars represents the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured at $0.9\ TeV$ using unlike-charge particle reference sample for different $n_{ch}$ intervals $p_{T} > 100\ MeV$ and $|\eta|<2.5$. The error bars represents only the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured at $0.9\ TeV$ using unlike-charge particle reference sample for different $k_{T}$ intervals with multiplicity $n_{ch} \ge 2$. The error bars represents only the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured at $7\ TeV$ using unlike-charge particle reference sample for different multiplicity intervals $n_{ch}$ with $p_{T} > 100\ MeV$ and $|\eta| < 2.5$. The error bars represents only the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured at $7\ TeV$ using unlike-charge particle reference sample for different $k_{T}$ intervals with multiplicity $n_{ch} \ge 2$. The error bars represents only the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured at $7\ TeV\ HM$ using unlike-charge particle reference sample for different $n_{ch}$ intervals $p_{T} > 100\ MeV$ and $|\eta|<2.5$. The error bars represents only the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured with $7\ TeV\ HM$ data using unlike-charge particle reference sample for different $k_{T}$ intervals with multiplicity $n_{ch} \ge 150$. The error bars represents only the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured at $7\ TeV$ using unlike-charge particle reference sample for different $k_{T}$ intervals within multiplicity interval $n_{ch} = 2-9$. The error bars represents only the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured at $7\ TeV$ using unlike-charge particle reference sample for different $k_{T}$ intervals within multiplicity interval $n_{ch} = 10-24$. The error bars represents only the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured at $7\ TeV$ using unlike-charge particle reference sample for different $k_{T}$ intervals within multiplicity interval $n_{ch} = 25-80$. The error bars represents only the statistical uncertainties.

The $R_{2}(Q)$ correlation function measured at $7\ TeV$ using unlike-charge particle reference sample for different $k_{T}$ intervals within multiplicity interval $n_{ch} = 81-125$. The error bars represents only the statistical uncertainties.

Differential cross section as a function of the photon ETARAP.

Differential cross section as a function of Q**2.

Differential cross section as a function of the photon ET in the ETARAP bins -1.2 to -0.6.

Differential cross section as a function of the photon ET in the ETARAP bins -0.6 to 0.2.

Differential cross section as a function of the photon ET in the ETARAP bins 0.2 to 0.9.

Differential cross section as a function of the photon ET in the ETARAP bins 0.9 to 1.4.

Differential cross section as a function of the photon ET in the ETARAP bins 1.4 to 1.8.

Differential cross section as a function of the photon ET in the higher Q**2 range > 40 GeV**2.

Differential cross section as a function of the photon ETARAP in the higher Q**2 range > 40 GeV**2.

Differential cross section for isolated photon production accompanied by non or at least 1-jet as a function of the photon ET.

Differential cross section for isolated photon production accompanied by non or at least 1-jet as a function of the photon ETARAP.

Differential cross section for isolated photon production accompanied by non or at least 1-jet as a function of Q**2.

The DVCS cross section as a function of T for 3 values of Q**2 at W = 82 GeV.

The DVCS cross section as a function of T for 3 values of W at Q**2 = 10 GeV**2.

Slope of the T distribution as a function of Q**2 for W = 82 GeV.

Slope of the T distribution as a function of W for Q**2 = 10 GeV**2.

The DVCS cross section as a function of T for 3 values of W at Q**2 = 8 GeV**2.

The DVCS cross section as a function of T for 3 values of W at Q**2 = 20 GeV**2.

Bin averaged differential cross sections of diffractive di-jet production as a function of Z(NAME=POMERON).

Bin averaged differential cross sections of diffractive di-jet production as a function centre of mass PT of the leading jet.

Bin averaged differential cross sections of diffractive di-jet production as a function of the pseudorapidity difference.

Bin averaged double differential cross sections of diffractive di-jet production as a function of Z(NAME=POMERON) in the (Q**2 + PT(LEADING JET)**2) range 29 to 50 GeV.

Bin averaged double differential cross sections of diffractive di-jet production as a function of Z(NAME=POMERON) in the (Q**2 + PT(LEADING JET)**2) range 50 to 70 GeV.

Bin averaged double differential cross sections of diffractive di-jet production as a function of Z(NAME=POMERON) in the (Q**2 + PT(LEADING JET)**2) range 70 to 100 GeV.

Bin averaged double differential cross sections of diffractive di-jet production as a function of Z(NAME=POMERON) in the (Q**2 + PT(LEADING JET)**2) range 100 to 200 GeV.

Double differential cross section as a function of ET integrated over the ET bin range and the Q**2 range 400 to 700 GeV**2.

Double differential cross section as a function of ET integrated over the ET bin range and the Q**2 range 700 to 5000 GeV**2.

Double differential cross section as a function of ET integrated over the ET bin range and the Q**2 range 5000 to 15000 GeV**2.

Single differential cross section as a function of ET integrated over the ET bin range.

Single differential cross section as a function of Q**2 integrated over the Q**2 bin range.

Normalised inclusive jet cross section as a function of ET in the Q**2 range 150 to 200 GeV**2.

Normalised inclusive jet cross section as a function of ET in the Q**2 range 200 to 270 GeV**2.

Normalised inclusive jet cross section as a function of ET in the Q**2 range 270 to 400 GeV**2.

Normalised inclusive jet cross section as a function of ET in the Q**2 range 400 to 700 GeV**2.

Normalised inclusive jet cross section as a function of ET in the Q**2 range 700 to 5000 GeV**2.

Normalised inclusive jet cross section as a function of ET in the Q**2 range 5000 to 15000 GeV**2.

Visible cross section for inclusive D*+- production with two jets.

Ratio of visible cross sections of inclusive D*+- production with and without the two jets.

Ratio of visible cross sections of inclusive D*+- production with and without the two jets.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of Q**2.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of Q**2.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of X.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of X.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of W.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of W.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of PT.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of PT.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of ETARAP.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of ETARAP.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of Z.

Differential cross section for inclusive D*+- production in the visible kinematic region as a function of Z.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Double differential cross section for inclusive D*+- production in bins of Q**2 and X.

Differential cross section for inclusive D*+- production as a function of Q**2 with the constraint that the transverse momentum of the D* in the virtual photon-proton centre-of-mass frame is > 2 GeV.

Differential cross section for inclusive D*+- production as a function of Q**2 with the constraint that the transverse momentum of the D* in the virtual photon-proton centre-of-mass frame is > 2 GeV.

Differential cross section for inclusive D*+- production as a function of X with the constraint that the transverse momentum of the D* in the virtual photon-proton centre-of-mass frame is > 2 GeV.

Differential cross section for inclusive D*+- production as a function of X with the constraint that the transverse momentum of the D* in the virtual photon-proton centre-of-mass frame is > 2 GeV.

Differential cross section for inclusive D*+- production as a function of PT with the constraint that the transverse momentum of the D* in the virtual photon-proton centre-of-mass frame is > 2 GeV.

Differential cross section for inclusive D*+- production as a function of PT with the constraint that the transverse momentum of the D* in the virtual photon-proton centre-of-mass frame is > 2 GeV.

Differential cross section for inclusive D*+- production as a function of ETARAP with the constraint that the transverse momentum of the D* in the virtualphoton-proton centre-of-mass frame is > 2 GeV.

Differential cross section for inclusive D*+- production as a function of ETARAP with the constraint that the transverse momentum of the D* in the virtualphoton-proton centre-of-mass frame is > 2 GeV.

Differential cross section for D*+- production with dijets as a function of Q**2.

Differential cross section for D*+- production with dijets as a function of Q**2.

Differential cross section for D*+- production with dijets as a function of X.

Differential cross section for D*+- production with dijets as a function of X.

Differential cross section for D*+- production with dijets as a function of ET(C=JET1).

Differential cross section for D*+- production with dijets as a function of ET(C=JET1).

Differential cross section for D*+- production with dijets as a function of M(C=JET2).

Differential cross section for D*+- production with dijets as a function of M(C=JET2).

Double differential cross section for D*+- production with dijets in bins of Q**2 and PHI(JET1)-PHI(JET2).

Double differential cross section for D*+- production with dijets in bins of Q**2 and PHI(JET1)-PHI(JET2).

Double differential cross section for D*+- production with dijets in bins of Q**2 and PHI(JET1)-PHI(JET2).

Double differential cross section for D*+- production with dijets in bins of Q**2 and PHI(JET1)-PHI(JET2).

Differential cross section for D*+- production with dijets as a function of pseudorapidity of the jet containing D*.

Differential cross section for D*+- production with dijets as a function of pseudorapidity of the jet containing D*.

Differential cross section for D*+- production with dijets as a function of pseudorapidity of the other jet.

Differential cross section for D*+- production with dijets as a function of pseudorapidity of the other jet.

Differential cross section for D*+- production with dijets as a function of the pseudorapidity difference of the two jets.

Differential cross section for D*+- production with dijets as a function of the pseudorapidity difference of the two jets.

Differential cross section for D*+- production with dijets as a function of X(C=GAMMA), the observed fraction of the virtual photon momentum carried by the partons.

Differential cross section for D*+- production with dijets as a function of X(C=GAMMA), the observed fraction of the virtual photon momentum carried by the partons.

Double differential cross section for D*+- production with dijets in bins of Q**2 and X(C=GAMMA), the observed fraction of the virtual photon momentum carried by the partons.

Double differential cross section for D*+- production with dijets in bins of Q**2 and X(C=GAMMA), the observed fraction of the virtual photon momentum carried by the partons.

Differential cross section for D*+- production with dijets as a function of X(C=GLUON), the observed fraction of the proton momentum carried by the gluon.

Differential cross section for D*+- production with dijets as a function of X(C=GLUON), the observed fraction of the proton momentum carried by the gluon.

Double differential cross section for D*+- production with dijets in bins of Q**2 and X(C=GLUON), the observed fraction of the proton momentum carried by the gluon.

Double differential cross section for D*+- production with dijets in bins of Q**2 and X(C=GLUON), the observed fraction of the proton momentum carried by the gluon.

Differential cross section for diffractive D*+- production in the DIS region as a function of the inelasticity Y.

Differential cross section for diffractive D*+- production in the DIS region as a function of Q**2.

Differential cross section for diffractive D*+- production in the DIS region as a function of X(NAME=POMERON).

Differential cross section for diffractive D*+- production in the DIS region as a function of Z(NAME=POMERON).

Differential cross section for diffractive D*+- production in the DIS region as a function of BETA.

Differential cross section for diffractive D*+- production in the Photoproduction region as a function of PT of the D*.

Differential cross section for diffractive D*+- production in the Photoproduction region as a function of ETARAP of the D*.

Differential cross section for diffractive D*+- production in the Photoproduction region as a function of the inlasticity Y.

Differential cross section for diffractive D*+- production in the Photoproduction region as a function of X(NAME=POMERON).

Differential cross section for diffractive D*+- production in the Photoproduction region as a function of Z(NAME=POMERON).

Differential cross section for diffractive D*+- production in the DIS region as a function of PT of the D* for the region X(NAME=POMERON) < 0.01.

Differential cross section for diffractive D*+- production in the DIS region as a function of ETARAP of the D*.for the region X(NAME=POMERON) < 0.01.

Differential cross section for diffractive D*+- production in the DIS region as a function of X(NAME=POMERON) for the region X(NAME=POMERON) < 0.01.

Differential cross section for diffractive D*+- production in the DIS region as a function of Z(NAME=POMERON) for the region X(NAME=POMERON) < 0.01.

Reduced cross section for diffractive D*+- production measured in the DIS region from the displaced track analysis.

Differential cross section for diffractive D*+- production measured in the Q**2 region 15 to 100 GeV**2 region as a function of M(X).

Fractional charm contribution to the diffractive cross section obtained from the displaced track method.

Bin averaged differential cross section for inclusive D* production in bins of PT(D*).

Bin averaged differential cross section for inclusive D* production in bins of ETARAP(D*).

Bin averaged differential cross section for inclusive D* production in bins of Z(D*).

Bin averaged differential cross section for inclusive D* production in bins of W.

Bin averaged differential cross section for inclusive D* production in bins of ETARAP for different PT ranges.

Bin averaged differential cross section for D*+ other jet production where 'other' jet does not contain D*.

Bin averaged differential cross section for D*+ other jet production where 'other' jet does not contain D*.

Bin averaged differential cross section for D*+ other jet production where 'other' jet does not contain D*.

Bin averaged differential cross section for D*+ other jet production where 'other' jet does not contain D*.

Bin averaged differential cross section for D*+ other jet production where 'other' jet does not contain D*.

Bin averaged differential cross section for D* tagged dijet production in bins of X(C=GAMMA), the fraction of the longitudinal photon momentum entering the hard scattering process.

Bin averaged differential cross section for D*+ other jet data sample as a function of the difference in the azimuthal angle of the D* and the jet.

Reduced cross section from the Minimum Bias data sample taken in 1997.

Reduced cross section from the complete ('all') data sample taken in 1997.

Reduced cross section from the Minimum Bias data sample taken in 1997.

Reduced cross section from the complete ('all') data sample taken in 1997.

Reduced cross section from the Minimum Bias data sample taken in 1997.

Reduced cross section from the complete ('all') data sample taken in 1997.

Reduced cross section from the Data sample taken in 1999 and 2000.

Reduced cross section from the Data sample taken in 1999 and 2000.

Details of systematic errors from the Minimum Bias data sample taken in 1997. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the Minimum Bias data sample taken in 1997. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the complete ('all') data sample taken in 1997. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the Minimum Bias data sample taken in 1997. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the complete ('all') data sample taken in 1997. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the Minimum Bias data sample taken in 1997. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the complete ('all') data sample taken in 1997. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the Minimum Bias data sample taken in 1997. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the complete ('all') data sample taken in 1997. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the Data sample taken in 1999 and 2000. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Details of systematic errors from the Data sample taken in 1999 and 2000. D_UNC ==> uncorrelated systematic error. D_LAR ==> LAr hadronic energy scale. D_ELE ==> SPACAL electromagnetic energy scale. D_THETA ==> scattered electron angle. D_NOISE ==> calorimeter noise treatment. D_XPOM ==> reweighting the simulation in X(pomeron). D_BETA ==> reweighting the simulation in BETA. D_BG ==> background subtraction. D_PLUG ==> plug energy scale. Q**2 ==> reweighting the simulation in Q**2. SPA ==> SPACAL hadromic energy scale.

Measured CHARM cross section as a function of ETARAP.

Measured CHARM cross section as a function of X(C=GAMMA).

Ratio of CHARM to inclusive cross sections.

Ratio of CHARM to inclusive cross sections.

Ratio of CHARM to inclusive cross sections.

Measured BOTTOM cross section as a function of PT.

Measured BOTTOM cross section as a function of ETARAP.

Measured BOTTOM cross section as a function of X(C=GAMMA).

Ratio of BOTTOM to inclusive cross sections.

Ratio of BOTTOM to inclusive cross sections.

Ratio of BOTTOM to inclusive cross sections.

Measured CHARM cross section as a function of PT.

Measured CHARM cross section as a function of ETARAP.

Ratio of CHARM to inclusive cross sections.

Ratio of CHARM to inclusive cross sections.

Measured BOTTOM cross section as a function of PT.

Measured BOTTOM cross section as a function of ETARAP.

Ratio of BOTTOM to inclusive cross sections.

Ratio of BOTTOM to inclusive cross sections.