Correlation matrix of the unfolding uncertainty between the inclusive-jet measurement and the previous dijet measurement. Correlations are given in percent.

Summary of different determinations of $\alpha_s(M_Z^2)$ at NNLO or higher order, adapted from PDG, see references therein. The red points are included in the PDG world average. The averages from each sub-field are shown as yellow bands and the world average as a blue band. A recent measurement from CMS using jet cross sections and the latest determination from HERAPDF, which are not yet included in the world average, are shown in green. The current determination, assuming half-correlated and half-uncorrelated scale uncertainties, is shown in black.

Value of the strong coupling $\alpha_s(\mu^2)$ as a function of the scale $\mu$. The data points indicate determinations from measurements that were performed close to the indicated scale. The uncertainties represent the full uncertainty of each determination. All depicted results were obtained at least at NNLO. They are based on data from $e^+e^-$, $ep$ and $pp$ collisions, as well as from $\tau$ lepton decays and quarkonium states. The solid blue line shows the PDG world average. Also shown are the $\alpha_s(M_Z^2)$ values corresponding to each data point.

Double-differential inclusive-jet cross sections using the alternative treatment of QED radiation, as explained in <a href="https://inspirehep.net/literature/2714089">the accompanying thesis</a> (section 9.5.3 and table C.7) and <a href="https://arxiv.org/abs/2405.18136">arXiv:2405.18136</a>. The alternative treatment affects the central value of the cross sections, $\sigma$, the QED correction factors $c_\text{QED}$ and their uncertainty and the sum of all uncorrelated uncertainties $\delta_\text{uncor}$. All other uncertainties and corrections are identical to Tables 1 and 2 and should be taken from there.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $p_{T,jet}^{lead}$ region of $2.5 \;\mathrm{GeV} < p_{T,jet}^{lead} < 7 \;\mathrm{GeV}$ for $N_{jet} \geq 3$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $p_{T,jet}^{lead}$ region of $7 \;\mathrm{GeV} < p_{T,jet}^{lead} < 12 \;\mathrm{GeV}$ for $N_{jet} \geq 1$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $p_{T,jet}^{lead}$ region of $7 \;\mathrm{GeV} < p_{T,jet}^{lead} < 12 \;\mathrm{GeV}$ for $N_{jet} \geq 2$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $p_{T,jet}^{lead}$ region of $7 \;\mathrm{GeV} < p_{T,jet}^{lead} < 12 \;\mathrm{GeV}$ for $N_{jet} \geq 3$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $p_{T,jet}^{lead}$ region of $12 \;\mathrm{GeV} < p_{T,jet}^{lead} < 30 \;\mathrm{GeV}$ for $N_{jet} \geq 1$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $p_{T,jet}^{lead}$ region of $12 \;\mathrm{GeV} < p_{T,jet}^{lead} < 30 \;\mathrm{GeV}$ for $N_{jet} \geq 2$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $p_{T,jet}^{lead}$ region of $12 \;\mathrm{GeV} < p_{T,jet}^{lead} < 30 \;\mathrm{GeV}$ for $N_{jet} \geq 3$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $Q^{2}$ region of $10 \;\mathrm{GeV}^{2} < Q^{2} < 50 \;\mathrm{GeV}^{2}$ for $N_{jet} \geq 1$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $Q^{2}$ region of $10 \;\mathrm{GeV}^{2} < Q^{2} < 50 \;\mathrm{GeV}^{2}$ for $N_{jet} \geq 2$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $Q^{2}$ region of $10 \;\mathrm{GeV}^{2} < Q^{2} < 50 \;\mathrm{GeV}^{2}$ for $N_{jet} \geq 3$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $Q^{2}$ region of $50 \;\mathrm{GeV}^{2} < Q^{2} < 100 \;\mathrm{GeV}^{2}$ for $N_{jet} \geq 1$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $Q^{2}$ region of $50 \;\mathrm{GeV}^{2} < Q^{2} < 100 \;\mathrm{GeV}^{2}$ for $N_{jet} \geq 2$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $Q^{2}$ region of $50 \;\mathrm{GeV}^{2} < Q^{2} < 100 \;\mathrm{GeV}^{2}$ for $N_{jet} \geq 3$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $Q^{2}$ region of $100 \;\mathrm{GeV}^{2} < Q^{2} < 350 \;\mathrm{GeV}^{2}$ for $N_{jet} \geq 1$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $Q^{2}$ region of $100 \;\mathrm{GeV}^{2} < Q^{2} < 350 \;\mathrm{GeV}^{2}$ for $N_{jet} \geq 2$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

<b>Note: in the paper, uncertainties are given in relative terms. The HEPData table contains absolute numbers. The original data file, containing relative uncertainties as in the paper, is available via the 'Resources' button above.</b> Differential cross sections, $d\sigma/d\Delta\phi$, in the $Q^{2}$ region of $100 \;\mathrm{GeV}^{2} < Q^{2} < 350 \;\mathrm{GeV}^{2}$ for $N_{jet} \geq 3$, as obtained from the data, ARIADNE MC simulations, and perturbative calculations at $\mathcal{O}(\alpha_{s})$ and $\mathcal{O}(\alpha_{s}^{2})$ accuracy. Other details are as in the caption to Table 1.

QED correction factors for inclusive measurement, as estimated with RAPGAP.

QED correction factors for $2.5 \;\mathrm{GeV} < p_{T,jet}^{lead} < 7 \;\mathrm{GeV}$ and $N_{jet} \geq 1$, as estimated with RAPGAP.

QED correction factors for $2.5 \;\mathrm{GeV} < p_{T,jet}^{lead} < 7 \;\mathrm{GeV}$ and $N_{jet} \geq 2$, as estimated with RAPGAP.

QED correction factors for $2.5 \;\mathrm{GeV} < p_{T,jet}^{lead} < 7 \;\mathrm{GeV}$ and $N_{jet} \geq 3$, as estimated with RAPGAP.

QED correction factors for $7 \;\mathrm{GeV} < p_{T,jet}^{lead} < 12 \;\mathrm{GeV}$ and $N_{jet} \geq 1$, as estimated with RAPGAP.

QED correction factors for $7 \;\mathrm{GeV} < p_{T,jet}^{lead} < 12 \;\mathrm{GeV}$ and $N_{jet} \geq 2$, as estimated with RAPGAP.

QED correction factors for $7 \;\mathrm{GeV} < p_{T,jet}^{lead} < 12 \;\mathrm{GeV}$ and $N_{jet} \geq 3$, as estimated with RAPGAP.

QED correction factors for $12 \;\mathrm{GeV} < p_{T,jet}^{lead} < 30 \;\mathrm{GeV}$ and $N_{jet} \geq 1$, as estimated with RAPGAP.

QED correction factors for $12 \;\mathrm{GeV} < p_{T,jet}^{lead} < 30 \;\mathrm{GeV}$ and $N_{jet} \geq 2$, as estimated with RAPGAP.

QED correction factors for $12 \;\mathrm{GeV} < p_{T,jet}^{lead} < 30 \;\mathrm{GeV}$ and $N_{jet} \geq 3$, as estimated with RAPGAP.

QED correction factors for $10 \;\mathrm{GeV}^{2} < Q^{2} < 50 \;\mathrm{GeV}^{2}$ and $N_{jet} \geq 1$, as estimated with RAPGAP.

QED correction factors for $10 \;\mathrm{GeV}^{2} < Q^{2} < 50 \;\mathrm{GeV}^{2}$ and $N_{jet} \geq 2$, as estimated with RAPGAP.

QED correction factors for $10 \;\mathrm{GeV}^{2} < Q^{2} < 50 \;\mathrm{GeV}^{2}$ and $N_{jet} \geq 3$, as estimated with RAPGAP.

QED correction factors for $50 \;\mathrm{GeV}^{2} < Q^{2} < 100 \;\mathrm{GeV}^{2}$ and $N_{jet} \geq 1$, as estimated with RAPGAP.

QED correction factors for $50 \;\mathrm{GeV}^{2} < Q^{2} < 100 \;\mathrm{GeV}^{2}$ and $N_{jet} \geq 2$, as estimated with RAPGAP.

QED correction factors for $50 \;\mathrm{GeV}^{2} < Q^{2} < 100 \;\mathrm{GeV}^{2}$ and $N_{jet} \geq 3$, as estimated with RAPGAP.

QED correction factors for $100 \;\mathrm{GeV}^{2} < Q^{2} < 350 \;\mathrm{GeV}^{2}$ and $N_{jet} \geq 1$, as estimated with RAPGAP.

QED correction factors for $100 \;\mathrm{GeV}^{2} < Q^{2} < 350 \;\mathrm{GeV}^{2}$ and $N_{jet} \geq 2$, as estimated with RAPGAP.

QED correction factors for $100 \;\mathrm{GeV}^{2} < Q^{2} < 350 \;\mathrm{GeV}^{2}$ and $N_{jet} \geq 3$, as estimated with RAPGAP.

The correlation matrix for the inclusive measurement. The azimuthal correlation angle $\Delta\phi$ of each lepton--leading-jet pair was assigned a bin ID between 0 to 59 segmented uniformly from 0 to $\pi$. This bin ID was offset by multiples of 60 based on the jet multiplicity so that the pair from a single jet event, as suggested by the MC simulation, was assigned a value between 0 to 59, dijet events were given 60 to 119, trijet 120 to 179, and four or more jets 180 to 239.

The correlation matrix for $2.5 \;\mathrm{GeV} < p_{T,jet}^{lead} < 7 \;\mathrm{GeV}$. Other details are as in the caption to Fig. 13.

The correlation matrix for $7 \;\mathrm{GeV} < p_{T,jet}^{lead} < 12 \;\mathrm{GeV}$. Other details are as in the caption to Fig. 13.

The correlation matrix for $12 \;\mathrm{GeV} < p_{T,jet}^{lead} < 30 \;\mathrm{GeV}$. Other details are as in the caption to Fig. 13.

The correlation matrix for $10 \;\mathrm{GeV}^{2} < Q^{2} < 50 \;\mathrm{GeV}^{2}$. Other details are as in the caption to Fig. 13.

The correlation matrix for $50 \;\mathrm{GeV}^{2} < Q^{2} < 100 \;\mathrm{GeV}^{2}$. Other details are as in the caption to Fig. 13.

The correlation matrix for $100 \;\mathrm{GeV}^{2} < Q^{2} < 350 \;\mathrm{GeV}^{2}$. Other details are as in the caption to Fig. 13.

The reduced cross section at Q**2 = 60 GeV**2 for centre-of-mass energy 318.

The reduced cross section at Q**2 = 80 GeV**2 for centre-of-mass energy 318.

The reduced cross section at Q**2 = 110 GeV**2 for centre-of-mass energy 318.

The reduced cross section at Q**2 = 24 GeV**2 for centre-of-mass energy 251.

The reduced cross section at Q**2 = 32 GeV**2 for centre-of-mass energy 251.

The reduced cross section at Q**2 = 45 GeV**2 for centre-of-mass energy 251.

The reduced cross section at Q**2 = 60 GeV**2 for centre-of-mass energy 251.

The reduced cross section at Q**2 = 80 GeV**2 for centre-of-mass energy 251.

The reduced cross section at Q**2 = 110 GeV**2 for centre-of-mass energy 251.

The reduced cross section at Q**2 = 24 GeV**2 for centre-of-mass energy 225.

The reduced cross section at Q**2 = 32 GeV**2 for centre-of-mass energy 225.

The reduced cross section at Q**2 = 45 GeV**2 for centre-of-mass energy 225.

The reduced cross section at Q**2 = 60 GeV**2 for centre-of-mass energy 225.

The reduced cross section at Q**2 = 80 GeV**2 for centre-of-mass energy 225.

The reduced cross section at Q**2 = 110 GeV**2 for centre-of-mass energy 225.

FL and F2 at Q**2 = 24 GeV**2 with no constraints on FL or F2.

FL and F2 at Q**2 = 32 GeV**2 with no constraints on FL or F2.

FL and F2 at Q**2 = 45 GeV**2 with no constraints on FL or F2.

FL and F2 at Q**2 = 60 GeV**2 with no constraints on FL or F2.

FL and F2 at Q**2 = 80 GeV**2 with no constraints on FL or F2.

FL and F2 at Q**2 = 110 GeV**2 with no constraints on FL or F2.

FL and F2 with the additional constraints that F2 >= 0 and 0 <= FL <= F2.

FL and F2 with the additional constraints that F2 >= 0 and 0 <= FL <= F2.

FL and F2 with the additional constraints that F2 >= 0 and 0 <= FL <= F2.

FL and F2 with the additional constraints that F2 >= 0 and 0 <= FL <= F2.

FL and F2 with the additional constraints that F2 >= 0 and 0 <= FL <= F2.

FL and F2 with the additional constraints that F2 >= 0 and 0 <= FL <= F2.

FL and R as a function of Q**2 with no constraints on F2 or FL. The quantites are quoted such that Q**2/X is constant for each value which correspinds to Y = 0.71 at Ecm=225 GeV.

FL and R as a function of Q**2 with the additional constraints that F2 >= 0 and 0 <= FL <= F2. The quantites are quoted such that Q**2/X is constant for each value which correspinds to Y = 0.71 at Ecm=225 GeV.

Percentage contributions of the various sources of systematic error for Q**2 = 24 GeV**2 for centrof-mass energy 318.

Percentage contributions of the various sources of systematic error for Q**2 = 32 GeV**2 for centrof-mass energy 318.

Percentage contributions of the various sources of systematic error for Q**2 = 45 GeV**2 for centrof-mass energy 318.

Percentage contributions of the various sources of systematic error for Q**2 = 60 GeV**2 for centrof-mass energy 318.

Percentage contributions of the various sources of systematic error for Q**2 = 80 GeV**2 for centrof-mass energy 318.

Percentage contributions of the various sources of systematic error for Q**2 = 110 GeV**2 for centrof-mass energy 318.

Percentage contributions of the various sources of systematic error for Q**2 = 24 GeV**2 for centrof-mass energy 251.

Percentage contributions of the various sources of systematic error for Q**2 = 32 GeV**2 for centrof-mass energy 251.

Percentage contributions of the various sources of systematic error for Q**2 = 45 GeV**2 for centrof-mass energy 251.

Percentage contributions of the various sources of systematic error for Q**2 = 60 GeV**2 for centrof-mass energy 251.

Percentage contributions of the various sources of systematic error for Q**2 = 80 GeV**2 for centrof-mass energy 251.

Percentage contributions of the various sources of systematic error for Q**2 = 110 GeV**2 for centrof-mass energy 251.

Percentage contributions of the various sources of systematic error for Q**2 = 24 GeV**2 for centrof-mass energy 225.

Percentage contributions of the various sources of systematic error for Q**2 = 32 GeV**2 for centrof-mass energy 225.

Percentage contributions of the various sources of systematic error for Q**2 = 45 GeV**2 for centrof-mass energy 225.

Percentage contributions of the various sources of systematic error for Q**2 = 60 GeV**2 for centrof-mass energy 225.

Percentage contributions of the various sources of systematic error for Q**2 = 80 GeV**2 for centrof-mass energy 225.

Percentage contributions of the various sources of systematic error for Q**2 = 110 GeV**2 for centrof-mass energy 225.

Distribution of D(SIG)/DM(P=6) as a function of M(P=6) .

Distribution of D(SIG)/DBETA as a function of BETA .

Distribution of D(SIG)/DX(NAME=POMERON) as a function of X(NAME=POMERON) .

Distribution of D(SIG)/DET(P=4,5,RF=CM) as a function of ET(P=4,5,RF=CM) .

Distribution of D(SIG)/DETARAP(P=4,5,RF=CM) as a function of ETARAP(P=4,5,RF=CM) .

Distribution of D(SIG)/DZ(NAME=POMERON) as a function of Z(NAME=POMERON) .

Distribution of D(SIG)/DX(NAME=GAMMA) as a function of X(NAME=GAMMA) .

Distribution of D2(SIG)/DZ(NAME=POMERON)/DET(P=4,RF=CM) as a function of Z(NAME=POMERON) for ET(P=4,RF=CM) from 5 to 6.5 GeV). .

Distribution of D2(SIG)/DZ(NAME=POMERON)/DET(P=4,RF=CM) as a function of Z(NAME=POMERON) for ET(P=4,RF=CM) from 6.5 to 8 GeV). .

Distribution of D2(SIG)/DZ(NAME=POMERON)/DET(P=4,RF=CM) as a function of Z(NAME=POMERON) for ET(P=4,RF=CM) from 8 to 16 GeV). .

Distribution of D2(SIG)/DZ(NAME=POMERON)/DQ**2) as a function of Z(NAME=POMERON) for Q**2 from 5 to 12 GeV**2). .

Distribution of D2(SIG)/DZ(NAME=POMERON)/DQ**2) as a function of Z(NAME=POMERON) for Q**2 from 12 to 25 GeV**2). .

Distribution of D2(SIG)/DZ(NAME=POMERON)/DQ**2) as a function of Z(NAME=POMERON) for Q**2 from 25 to 50 GeV**2). .

Distribution of D2(SIG)/DZ(NAME=POMERON)/DQ**2) as a function of Z(NAME=POMERON) for Q**2 from 50 to 100 GeV**2). .

Differential cross section DSIG/DETARAP(P=4) in bins of ETARAP(P=4) .

Differential cross section DSIG/D(ETARAP(P=5)-ETARAP(P=6)) in bins of ETARAP(P=5)-ETARAP(P=6) .

Differential cross section DSIG/D(ETARAP(P=5)-ETARAP(P=6)) in bins of ETARAP(P=4)-ETARAP(P=5) .

Differential cross section DSIG/D(ETARAP(P=5)-ETARAP(P=6)) in bins of ETARAP(P=4)-ETARAP(P=5) .

Differential cross section DSIG/D(ETARAP(P=5)-ETARAP(P=6)) in bins of ETARAP(P=4)-ETARAP(P=5) .

Differential cross section D3SIG/DQ**2/DET(P=4)**2/DETARAP(P=4) in bins of ETARAP(P=4) for Q**2 from 20 TO 40 GeV*2 and ET(P=4)**2 range from 25 to 35 GeV**2 .

Differential cross section D3SIG/DQ**2/DET(P=4)**2/DETARAP(P=4) in bins of ETARAP(P=4) for Q**2 from 20 TO 40 GeV*2 and ET(P=4)**2 range from 36 to 100 GeV**2 .

Differential cross section D3SIG/DQ**2/DET(P=4)**2/DETARAP(P=4) in bins of ETARAP(P=4) for Q**2 from 20 TO 40 GeV*2 and ET(P=4)**2 range from 100 to 400 GeV**2 .

Differential cross section D3SIG/DQ**2/DET(P=4)**2/DETARAP(P=4) in bins of ETARAP(P=4) for Q**2 from 40 to 100 GeV*2 and ET(P=4)**2 range from 25 to 35 GeV**2 .

Differential cross section D3SIG/DQ**2/DET(P=4)**2/DETARAP(P=4) in bins of ETARAP(P=4) for Q**2 from 40 to 100 GeV*2 and ET(P=4)**2 range from 36 to 100 GeV**2 .

Differential cross section D3SIG/DQ**2/DET(P=4)**2/DETARAP(P=4) in bins of ETARAP(P=4) for Q**2 from 40 to 100 GeV*2 and ET(P=4)**2 range from 100 to 400 GeV**2 .

Measurement of the spin density matrix element r_1_11 as a function of Q**2.

Measurement of the spin density matrix element r_1_00 as a function of Q**2.

Measurement of the spin density matrix element RE(r_1_10) as a function of Q**2.

Measurement of the spin density matrix element r_1_1-1 as a function of Q**2.

Measurement of the spin density matrix element IM(r_2_10) as a function of Q**2.

Measurement of the spin density matrix element IM(r_2_1-1) as a function of Q**2.

Measurement of the spin density matrix element r_5_11 as a function of Q**2.

Measurement of the spin density matrix element r_5_00 as a function of Q**2.

Measurement of the spin density matrix element RE(r_5_10) as a function of Q**2.

Measurement of the spin density matrix element r_5_1-1 as a function of Q**2.

Measurement of the spin density matrix element IM(r_6_10) as a function of Q**2.

Measurement of the spin density matrix element IM(r_6_1-1) as a function of Q**2.

Measurement of the differential cross section DSIG/DT as a function of ABS(T) for the Q**2 region 2 to 4 and 4 to 6.5 GeV.

Measurement of the differential cross section DSIG/DT as a function of ABS(T) for the Q**2 region 6.5 to 10 and 10 to 15 GeV.

Measurement of the differential cross section DSIG/DT as a function of ABS(T) for the Q**2 region 15 to 30 and 30 to 80 GeV.

Measured values of the SLOPE of the DSIG/DT distribution as a function of Q**2.

Cross section as a function of Q**2 for mean value of W = 90 GeV**2.

Cross section as a function of W for the Q**2 ranges 2 to 3, 3 to 5 and 5 to 7 GeV.

Cross section as a function of W for the Q**2 ranges 7 to 10, 10 to 22 and 22 to 80 GeV.

Measurement of the power dependence on W of the cross section as a function of Q**2.

Measurement of the spin density matrix element r_04_00 and the ratio of cross sections for longitudinally and transversely polarized photons as a function of Q**2 at mean W = 90 GeV.

Measurement of the spin density matrix element r_04_00 and ratio of the longitudinally and transversely polarized photon cross section as a function of W for the Q**2 range 2 to 3 GeV.

Measurement of the spin density matrix element r_04_00 and ratio of the longitudinally and transversely polarized photon cross section as a function of W for the Q**2 range 3 to 7 GeV.

Measurement of the spin density matrix element r_04_00 and ratio of the longitudinally and transversely polarized photon cross section as a function of W for the Q**2 range 7 to 12 GeV.

Measurement of the spin density matrix element r_04_00 and ratio of the longitudinally and transversely polarized photon cross section as a function of W for the Q**2 range 12 to 50 GeV.

Measurement of the spin density matrix element r_04_00 and the ratio of the longitudinally and transversely polarized photon cross sections as a function of ABS(T) in the Q**2 range 2 to 5 GeV**2 and W range 32 to 120 GeV.

Measurement of the spin density matrix element r_04_00 and the ratio of the longitudinally and transversely polarized photon cross sections as a function of ABS(T) in the Q**2 range 5 to 50 GeV**2 and W range 40 to 160 GeV.

Double differential cross sections as a funtion of PT**2 for the XL range 0.50 TO 0.56. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.56 TO 0.62. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.62 TO 0.65. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.65 TO 0.68. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.68 TO 0.71. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.71 TO 0.74. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.74 TO 0.77. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.77 TO 0.80. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.80 TO 0.83. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.83 TO 0.86. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.86 TO 0.89. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.89 TO 0.92. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.92 TO 0.95. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.95 TO 0.98. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Double differential cross sections as a funtion of PT**2 for the XL range 0.98 TO 1.00. The methods S123 and S456 are the results using different stations of the silicon microstrip detectors.

Leading proton production rate as a funtion of XL in 3 PT**2 ranges.

Leading proton production rate as a funtion of XL for the PT**2 region < 0.5 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 9.6E-5 and mean Q**2 of 4.2 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.7E-4 and mean Q**2 of 4.2 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 3.5E-4 and mean Q**2 of 4.2 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 6.9E-4 and mean Q**2 of 4.2 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.46E-3 and mean Q**2 of 4.2 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.9E-4 and mean Q**2 of 7.3 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 3.4E-4 and mean Q**2 of 7.3 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 6.9E-4 and mean Q**2 of 7.3 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.36E-3 and mean Q**2 of 7.3 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 2.67E-3 and mean Q**2 of 7.3 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 2.6E-4 and mean Q**2 of 11 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 4.6E-4 and mean Q**2 of 11 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 9.2E-4 and mean Q**2 of 11 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.83E-3 and mean Q**2 of 11 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 3.98E-3 and mean Q**2 of 11 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 5.1E-4 and mean Q**2 of 22 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 9.2E-4 and mean Q**2 of 22 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.84E-3 and mean Q**2 of 22 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 3.66E-3 and mean Q**2 of 22 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 7.83E-3 and mean Q**2 of 22 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.03E-3 and mean Q**2 of 44 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.86E-3 and mean Q**2 of 44 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 3.68E-3 and mean Q**2 of 44 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 7.33E-3 and mean Q**2 of 44 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.54E-2 and mean Q**2 of 44 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 2.00E-3 and mean Q**2 of 88 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 3.59E-3 and mean Q**2 of 88 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 7.37E-3 and mean Q**2 of 88 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.42E-2 and mean Q**2 of 88 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 3.01E-2 and mean Q**2 of 88 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 4.00E-3 and mean Q**2 of 237 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 7.52E-3 and mean Q**2 of 237 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 1.47E-2 and mean Q**2 of 237 GeV**2.

Leading proton production rate as a function of XL for the PT**2 region < 0.5 GeV**2, a mean X of 3.25E-2 and mean Q**2 of 237 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.04 to 0.15 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of XL for protons with PT**2 in the range 0.15 to 0.5 GeV**2.

Leading proton production rate as a function of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production rate as a function of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production rate, averaged over X, as a function of Q**2 for protons with PT**2 < 0.5 GeV**2 in two XL ranges.

Leading proton production structure function F2(C=Lp) as a fujnction of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production structure function F2(C=Lp) as a fujnction of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production structure function F2(C=Lp) as a fujnction of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production structure function F2(C=Lp) as a fujnction of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production structure function F2(C=Lp) as a fujnction of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production structure function F2(C=Lp) as a fujnction of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Leading proton production structure function F2(C=Lp) as a fujnction of X in Q**2 bins for protons with XL in the range 0.32 to 0.92 and PT**2 < 0.5 GeV**2.

Measured differential cross section as a function of the muon pseudorapidity.

Measured differential cross section as a function of the jet transverse momentum.

Measured differential cross section as a function of the jet pseudorapidity.

Measured cross sections for beauty production with a muon and jet for the Q**2 bin 2 to 4 GeV**2.

Measured cross sections for beauty production with a muon and jet for the Q**2 bin 4 to 20 GeV**2.

Measured cross sections for beauty production with a muon and jet for the Q**2 bin 20 to 45 GeV**2.

Measured cross sections for beauty production with a muon and jet for the Q**2 bin 45 to 100 GeV**2.

Measured cross sections for beauty production with a muon and jet for the Q**2 bin 100 to 250 GeV**2.

Measured cross sections for beauty production with a muon and jet for the Q**2 bin 250 to 3000 GeV**2.

Extracted values of F2 for B-BBAR production at an X value of 0.00013. The second systematic error is the uncertainty on the extrapolation to the full muon and jet phase space.

Extracted values of F2 for B-BBAR production at an X value of 0.0002. The second systematic error is the uncertainty on the extrapolation to the full muon and jet phase space.

Extracted values of F2 for B-BBAR production at an X value of 0.0005. The second systematic error is the uncertainty on the extrapolation to the full muon and jet phase space.

Extracted values of F2 for B-BBAR production at an X value of 0.002. The second systematic error is the uncertainty on the extrapolation to the full muon and jet phase space.

Extracted values of F2 for B-BBAR production at an X value 0.005.

Extracted values of F2 for B-BBAR production at an X value of 0.013. The second systematic error is the uncertainty on the extrapolation to the full muon and jet phase space.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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