Inclusive Jet Cross Section ${\rm\frac{d\sigma_{jet}}{dP_T}}$.

2-Jet Cross Section ${\rm\frac{d\sigma_{2-jet}}{d\langle P_T \rangle}}$.

3-Jet Cross Section ${\rm\frac{d\sigma_{3-jet}}{d\langle P_T \rangle}}$.

Inclusive Jet Cross Section ${\rm\frac{d^2\sigma_{jet}}{dQ^2dP_T}}$.

2-Jet Cross Section ${\rm\frac{d^2\sigma_{2-jet}}{dQ^2d\langle P_T \rangle}}$.

2-Jet Cross Section ${\rm\frac{d^2\sigma_{2-jet}}{dQ^2d\xi}}$.

3-Jet Cross Section ${\rm\frac{d^2\sigma_{3-jet}}{dQ^2d\langle P_T \rangle}}$.

3-Jet to 2-Jet Cross Sections Ratio ${\rm\frac{d\sigma_{3-jet}}{dQ^2}/\frac{d\sigma_{2-jet}}{dQ^2}}$.

3-Jet to 2-Jet Cross Sections Ratio ${\rm\frac{d\sigma_{3-jet}}{d\langle P_T \rangle}/\frac{d\sigma_{2-jet}}{d\langle P_T \rangle}}$.

3-Jet to 2-Jet Cross Sections Ratio ${\rm\frac{d^2\sigma_{3-jet}}{dQ^2d\langle P_T \rangle}/\frac{d^2\sigma_{2-jet}}{dQ^2d\langle P_T \rangle}}$.

3-jet cross section normalised to 2-jet cross section in bins of $Q^{2}$.

Normalised inclusive jet cross section in bins of $Q^{2}$ and $P_{T}$.

Normalised 2-jet cross section in bins of $Q^{2}$ and $\langle P_{T} \rangle$.

Normalised 2-jet cross sections in bins of $Q^2$ and $\xi$.

Measured J/PSI differential photoproduction cross section as a function of PT^2 in the Z range 0.10-0.30.

Measured J/PSI differential photoproduction cross section as a function of PT^2 in the Z range 0.30-0.45.

Measured J/PSI differential photoproduction cross section as a function of PT^2 in the Z range 0.45-0.60.

Measured J/PSI differential photoproduction cross section as a function of PT^2 in the Z range 0.60-0.75.

Measured J/PSI differential photoproduction cross section as a function of PT^2 in the Z range 0.75-0.90.

Measured J/PSI differential photoproduction cross section as a function of Z in the PT range 1.0-2.0.

Measured J/PSI differential photoproduction cross section as a function of Z in the PT range 2.0-3.0.

Measured J/PSI differential photoproduction cross section as a function of Z in the PT range 3.0-4.5.

Measured J/PSI differential photoproduction cross section as a function of Z in the PT range >-4.5.

Normalised cross sections of forward neutron production in DIS as a function of XF. For each measurement, the statistical, the uncorrelated systematic uncertainties and the bin-to-bin correlated systematic uncertainties due to the FNC absolute energy scale (EFNC), the measurement of the particle impact position in the FNC (XYFNC) and the model dependence of the data correction (model) are given.

Double-differential trijet cross sections measured as a function of Q**2 and MEAN(PT(3JET)) using the kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.9% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential trijet cross sections measured as a function of Q**2 and XI(3) using the kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.9% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential inclusive jet cross sections measured as a function of Q**2 and PT(JET) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.5% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential dijet cross sections measured as a function of Q**2 and MEAN(PT(2JET)) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.6% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential dijet cross sections measured as a function of Q**2 and XI(2) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.6% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential trijet cross sections measured as a function of Q**2 and MEAN(PT(3JET)) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.9% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential trijet cross sections measured as a function of Q**2 and XI(3) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.9% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised inclusive jet cross sections measured as a function of Q**2 and PT(JET) using the kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.5% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised dijet cross sections measured as a function of Q**2 and MEAN(PT(2JET)) using the kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.6% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised inclusive dijet cross sections measured as a function of Q**2 and XI(2) using the kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.6% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised trijet cross sections measured as a function of Q**2 and MEAN(PT(3JET)) using the kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.9% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised trijet cross sections measured as a function of Q**2 and XI(3) using the kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.9% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised inclusive jet cross sections measured as a function of Q**2 and PT(JET) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.5% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised dijet cross sections measured as a function of Q**2 and MEAN(PT(2JET)) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.6% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised inclusive dijet cross sections measured as a function of Q**2 and XI(2) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.6% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised trijet cross sections measured as a function of Q**2 and MEAN(PT(3JET)) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.9% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

Double-differential normalised trijet cross sections measured as a function of Q**2 and XI(3) using the anti-kT jet algorithm. The total systematic uncertainty sums all systematic uncertainties in quadrature, including the uncertainty due to the LAr noise of 0.9% and the total normalisation uncertainty of 2.9%. The correction factors on the theoretical cross sections C(HAD) and C(EW) are listed in the rightmost columns.

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.

Differential K0S cross section as a function of Q**2 in the laboratory frame.

Differential K0S cross section as a function of X in the laboratory frame.

Differential K0S cross section as a function of PT in the laboratory frame.

Differential K0S cross section as a function of ETARAP in the laboratory frame.

Differential LAMBDA cross section as a function of Q**2 in the laboratory frame.

Differential LAMBDA cross section as a function of X in the laboratory frame.

Differential LAMBDA cross section as a function of PT in the laboratory frame.

Differential LAMBDA cross section as a function of ETARAP in the laboratoryframe.

Differential K0S cross section as a function of PT in the target hemisphere of the Breit frame.

Differential K0S cross section as a function of PT in the current hemisphere of the Breit frame.

Differential K0S cross section as a function of XP(Breit) in the target hemisphere of the Breit frame.

Differential K0S cross section as a function of XP(Breit) in the current hemisphere of the Breit frame.

Differential LAMBDA cross section as a function of PT in the target hemisphere of the Breit frame.

Differential LAMBDA cross section as a function of PT in the current hemisphere of the Breit frame.

Differential LAMBDA cross section as a function of XP(Breit) in the target hemisphere of the Breit frame.

Differential LAMBDA cross section as a function of XP(Breit) in the currenthemisphere of the Breit frame.

Value of the LAMBDA/K0S cross section ratio as a function of Q**2.

Value of the LAMBDA/K0S cross section ratio as a function of X.

Value of the LAMBDA/K0S cross section ratio as a function of PT.

Value of the LAMBDA/K0S cross section ratio as a function of ETARAP.

Value of the LAMBDA/K0S cross section ratio as a function of PT in the target hemisphere of the Breit frame.

Value of the LAMBDA/K0S cross section ratio as a function of PT in the current hemisphere of the Breit frame.

Value of the LAMBDA/K0S cross section ratio as a function of X in the target hemisphere of the Breit frame.

Value of the LAMBDA/K0S cross section ratio as a function of X in the current hemisphere of the Breit frame.

Value of the HADRON+-/K0S cross section ratio as a function of Q**2.

Value of the HADRON+-/K0S cross section ratio as a function of X.

Value of the HADRON+-/K0S cross section ratio as a function of PT.

Value of the HADRON+-/K0S cross section ratio as a function of ETARAP.

Measured invariant cross section for DEUTBAR production.

The measured DEUT to P production ratio and the coalesence parameter B2 as a function of PT/M.

The measured DEUTBAR to PBAR production ratio and the coalesence parameter B2 as a function of PT/M.

The measured PBAR to P and DEUTBAR to DEUT ratios as a function of PT/M.

Di-jet rates for 'Sum' scenario for jet energy cuts.