Projections of the correlation function C.

Projections of the correlation function C.

Projections of the correlation function C.

Projections of the correlation function C.

Pion HBT radii for the 5% most central collisions.

Pion HBT radii for the 5% most central collisions from the STAR experiment at 200 GeV taken from Adams et al. PR C71(2005)044906.

Ratio of Pion HBT radii for the OUT projection to that for the SIDE projection for the 5% most central collisions.

Ratio of Pion HBT radii for the OUT projection to that for the SIDE projection for the 5% most central collisions from the STAR experiment at 200 GeV taken from Adams et al. PR C71(2005)044906.;.

Pion HBT radii at KT=0.3 for the 5% most central collisions as a function of the central charged multiplicity. Data from other experiments is shown for comparison.

Product of the three HBT radii at KT=0.3 for the 5% most central collisions as a function of the central charged multiplicity. Data from other experiments is shown for comparison.

The decoupling time extracted from R_long(KT) as a function of the central charged multiplicity. Data from other experiments is shown for comparison.

Additional information containing number of events which were used to reconstruct the numvers matching to Figure 1 and 2.

Additional information containing number of events which were used to reconstruct the numvers matching to Figure 1 and 2.

Additional information containing number of events which were used to reconstruct the numvers matching to Figure 1 and 2.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Au+Au collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 62.4 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 22.5 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 22.5 GeV Cu+Cu collisions.

The uncorrected multiplicity distributions of charged hadrons with 0.2 < $p_T$ < 2.0 GeV/$c$ for 200 GeV $p$+$p$ collisions.

The mean from the NBD fit as a function of $N_{part}$ for 200 GeV Au+Au collisions over the range 0.2 < $p_T$ < 2.0 GeV/$c$.

The mean from the NBD fit as a function of $N_{part}$ for 62.4 GeV Au+Au collisions over the range 0.2 < $p_T$ < 2.0 GeV/$c$.

The mean from the NBD fit as a function of $N_{part}$ for 200 GeV Cu+Cu collisions over the range 0.2 < $p_T$ < 2.0 GeV/$c$.

The mean from the NBD fit as a function of $N_{part}$ for 62.4 GeV Cu+Cu collisions over the range 0.2 < $p_T$ < 2.0 GeV/$c$.

The mean from the NBD fit as a function of $N_{part}$ for 22.5 GeV Cu+Cu collisions over the range 0.2 < $p_T$ < 2.0 GeV/$c$.

Fluctuations expressed as the scaled variance as a function of centrality for 200 GeV Au+Au collisions in the range 0.2 < $p_T$ < 2.0 GeV/$c$.

Fluctuations expressed as the scaled variance as a function of $N_{part}$ for 200 GeV Au+Au collisions for 0.2 < $p_T$ < 2.0 GeV/$c$.

Fluctuations expressed as the scaled variance as a function of $N_{part}$ for 62.4 GeV Au+Au collisions for 0.2 < $p_T$ < 2.0 GeV/$c$.

Fluctuations expressed as the scaled variance as a function of $N_{part}$ for 200 GeV Cu+Cu collisions for 0.2 < $p_T$ < 2.0 GeV/$c$.

Fluctuations expressed as the scaled variance as a function of $N_{part}$ for 62.4 GeV Cu+Cu collisions for 0.2 < $p_T$ < 2.0 GeV/$c$.

Fluctuations expressed as the scaled variance as a function of $N_{part}$ for 22.5 GeV Cu+Cu collisions for 0.2 < $p_T$ < 2.0 GeV/$c$.

Scaled variance for 200 GeV Au+Au collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

Scaled variance for 200 GeV Au+Au collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

Scaled variance for 62.4 GeV Au+Au collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

Scaled variance for 62.4 GeV Au+Au collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

Scaled variance for 62.4 GeV Au+Au collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

Scaled variance for 200 GeV Cu+Cu collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

Scaled variance for 200 GeV Cu+Cu collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

Scaled variance for 200 GeV Cu+Cu collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

Scaled variance for 62.4 GeV Cu+Cu collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

Scaled variance for 62.4 GeV Cu+Cu collisions plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 200 GeV Au+Au collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 200 GeV Au+Au collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 62.4 GeV Au+Au collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 62.4 GeV Au+Au collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 62.4 GeV Au+Au collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 200 GeV Cu+Cu collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 200 GeV Cu+Cu collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 200 GeV Cu+Cu collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 62.4 GeV Cu+Cu collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The inverse of the parameter $k_{NBD}$ from the Negative Binomial Distribution fits for 62.4 GeV Cu+Cu collisions. The fluctuations are plotted as a function of $N_{part}$ for several $p_T$ ranges.

The scaled variance as a funciton of $N_{part}$ for 200 GeV Au+Au collisions in the range 0.2 < $p_T$ < 2.0 GeV/$c$.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

The correlation of the clan model parameters $\bar{n_c}$ and $\bar{N_c}$ for all of the collision species measured as a function of centrality.

Single differential visible cross section as a function of LOG(X).

Single differential visible cross section as a function of ETARAP.

Single differential visible cross section as a function of Q**2.

Single differential visible cross section as a function of Z.

Double differential visible cross section as a function of ETARAP and Q**2.

Double differential visible cross section as a function of PT and Q**2.

Double differential visible cross section as a function of ETARAP and Z.

Double differential visible cross section as a function of PT and ETARAP.

Double differential visible cross section as a function of PT and Z.

The inclusive visible D*+ cross section extracted in the DGLAP scheme.

The charm structure function extracted in both the DGLAP and CCFM scheme.

The inclusive 3-JET cross section as a function of Bjorken scaling variableX for the Q**2 range 150 to 5000 GeV**2.

The inclusive 3-JET cross section as a function of the invariant 3-JET massfor the Q**2 range 5 to 100 GeV**2.

The inclusive 3-JET cross section as a function of the invariant 3-JET massfor the Q**2 range 150 to 5000 GeV**2.

Distribution of jet energy fraction X3 = 2E(P=4)/M(P=4_5_6) in the 3 JET centre-of-mass frame for Q**2 from 5 to 100 GeV**2.

Distribution of jet energy fraction X3 = 2E(P=4)/M(P=4_5_6) in the 3 JET centre-of-mass frame for Q**2 from 150 to 5000 GeV**2.

Distribution of jet energy fraction X4 = 2E(P=5)/M(P=4_5_6) in the 3 JET centre-of-mass frame for Q**2 from 5 to 100 GeV**2.

Distribution of jet energy fraction X4 = 2E(P=5)/M(P=4_5_6) in the 3 JET centre-of-mass frame for Q**2 from 150 to 5000 GeV**2.

Distribution of COS(THETA(C=3)) in the 3 JET centre-of-mass frame at Q**2 from 5 to 100 GeV**2. THETA(C=3) is the angle of the most energetic jet with respect to the proton beam direction.

Distribution of COS(THETA(C=3)) in the 3 JET centre-of-mass frame at Q**2 from 150 to 5000 GeV**2. THETA(C=3) is the angle of the most energetic jet with respect to the proton beam direction.

Distribution of PSI(C=3)) in the 3 JET centre-of-mass frame at Q**2 from 5 to 100 GeV**2. PSI(C=3) is the angle between the plane spanned by the highest energy jet and the proton beam and the plane containing the 3 jets.

Distribution of COS(THETA(C=3)) in the 3 JET centre-of-mass frame at Q**2 from 150 to 5000 GeV**2. PSI(C=3) is the angle between the plane spanned by the highest energy jet and the proton beam and the plane containing the 3 jets.

The NC single differential cross section, as a function of Q**2 in the range from 200 to 30000 Gev**2, for Y < 0.9 after correction (KCOR) according to theStandard Model expectation from the measured kinematic cuts y < 0.63 for Q**2 < 890 GeV**2. The first DSYS error is the uncorrelated systematic error and the second is the correlated systematic error.

No description provided.

The structure function, F2, and the reduced cross section, in NC DIS scattering at Q**2 from 150 to 30000 GeV**2 as a function if x and y. The individual corrections used to calculate F2 from the cross sections are given in the following table.

The various corrections to the cross sections used to calcuate the F2 values given in the previous table. See the text of the paper for more details.

The CC double differential cross section and the structure function term PHI(C=CC) - see text of the paper for details - at Q**2 from 150 to 1 5000 GeV**2 as a function of both x and y. Also tabulated are the QED corrections to the data, which have already been applied.

CT = The various sources of error (in percent) to the individual NC reduced cross section given in table 6 - see text of paper for more details;DTOT - TOTAL error. DSTA - STATISTICAL error. DUNC - UNCORRELATED SYSTEMATIC error. DUNC(E) - UNCORRELATED SYSTEMATIC error from the positron energy. DUNC(H) - UNCORRELATED SYSTEMATIC error from the hadronic energy. DCOR - CORRELATED SYSTEMATIC error. DCOR(E+) - CORRELATED SYSTEMATIC from one sig variation in the positron energy. DCOR(T+) - CORRELATED SYSTEMATIC from one sig variation in the positron polar angle. DCOR(H+) - CORRELATED SYSTEMATIC from one sig variation in the hadron energy. DCOR(N+) - CORRELATED SYSTEMATIC from one sig variation in the noise subtraction. DCOR(B+) - CORRELATED SYSTEMATIC from one sig variation in the background subtraction.

The various sources of error (in percent) to the individual CC double differential cross sections given in table 7 - see text of paper for more details. DTOT - TOTAL error. DSTA - STATISTICAL error. DUNC - UNCORRELATED SYSTEMATIC error. DUNC(H) - UNCORRELATED SYSTEMATIC error from the hadronic energy. DCOR - CORRELATED SYSTEMATIC error. DCOR(V+) - CORRELATED SYSTEMATIC from one sig variationin the cut on the Vap/Vp ratio. DCOR(H+) - CORRELATED SYSTEMATIC from one sig variation in the hadron energy. DCOR(N+) - CORRELATED SYSTEMATIC from one sig variation in the noise subtraction. DCOR(B+) - CORRELATED SYSTEMATIC from one sig variation in the background subtraction.

The structure function xF3 dtermined by combining the present NC E- data with previously measured E+ data at a proton enetrgy of 820 GeV. (Adloff et al. EPJ C13 (609) 2000.). The luminosity uncertainties of the E+ P and E- P data sets are included in the systematic error.

The total CC cross section in the region Q**2 > 1000 GeV**2 and Y > 0.9 after applying a small correction factor from the measured Y range from 0.03 0.85.

The longitudinal structure function FL determined from the present data. The first DSYS error is the combined uncorrelated and correlated systematics. The second DSYS error is due to the uncertainties corrected with the representationsof F2 in the derivative method for Q**2 < 10 GeV**2, and in the QCD extrapolati on method for Q**2 > 10 GeV**2.

The measured values of the derivative DF2/DLN(Q**2), calculated at fixed X bins.

Value of ALPHAS obtained by combining the H1 data with MU P scattering dataof BCDMS at large X.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of the invariant mass of the diffractive system (X).

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of W.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of X(NAME=POMERON).

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of BETA=X/X(NAME=POMERON).

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), the fraction of the hadronic final state energy of the DD system which is contained in the two jets.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of X(NAME=GAMMA,C=JETS), the fraction ofthe photon momentum which enters the hard scattering.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of E(NAME=REM,C=GAMMA), the energy sum of all final state hadrons in the photon hemisphere (ETARAP<0) which lie outside the two hightest PT(RF=CM) jet cones.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), for the LOG10(X(NAME=POMERON)) range -1.5 TO -1.3.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), for the LOG10(X(NAME=POMERON)) range -1.75 TO -1.5.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), for the LOG10(X(NAME=POMERON)) range -2.0 TO -1.75.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), for the LOG10(X(NAME=POMERON)) range < -2.0.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), for the Q**2 + PT**2 range 20 TO 35 GEV**2.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), for the Q**2 + PT**2 range 35 TO 45 GEV**2.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), for the Q**2 + PT**2 range 45 TO 60 GEV**2.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), for the Q**2 + PT**2 range > 60 GEV**2.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Q**2 for the restricted interval X(NAME=POMERON) < 0.01.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of the average transverse momentum of the two jets in the c.m.frame for the restricted interval X(NAME=POMERON) < 0.01.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of Z(NAME=POMERON,C=JETS), the fraction of the hadronic final state energy of the DD system which is contained in the two jets for the restricted interval X(NAME=POMERON) < 0.01.

Average values, over the specified interval, of the differential hadron level dijet cross section as a function of PT(NAME=REM,C=POMERON), the PT sum of all final state hadrons in the pomeron hemisphere (ETARAP>0) which lie outside the two hightest PT(RF=CM) jet cones.

Average values, over the specified interval, of the differential hadron level three-jet cross section as a function of the invariant mass of the 3 jet system.

Average values, over the specified interval, of the differential hadron level three-jet cross section as a function of Z(NAME=POMERON,C=3-JETS).

Inclusive di-jet cross section as a function of the di-jet mass M and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of Y (inelasticity) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of ETAPRIME ((ETARAP(P=3)-ETARAP(P=4))/2) and ET.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of ETAPRIME ((ETARAP(P=3)-ETARAP(P=4))/2) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of ETARAP(forward jet in lab frame) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive di-jet cross section as a function of ETARAP(backward jet in lab frame) and Q**2.. Data are analysed in the Breit frame using the inclusive kT alogrithm.

Inclusive single jet cross section as a function of ET and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive dijet cross section as a function Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of ET and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of the di-jet mass M and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of Y (inelasticity) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of ETAPRIME ((ETARAP(P=3)-ETARAP(P=4))/2) and ET.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of ETAPRIME ((ETARAP(P=3)-ETARAP(P=4))/2) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of ETARAP(forward jet in lab frame) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive di-jet cross section as a function of ETARAP(backward jet in lab frame) and Q**2.. Data are analysed in the Breit frame using the Aachen alogrithm.

Inclusive dijet cross section as a function Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of ET and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of the di-jet mass M and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of Y (inelasticity) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of ETAPRIME ((ETARAP(P=3)-ETARAP(P=4))/2) and ET.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of ETAPRIME ((ETARAP(P=3)-ETARAP(P=4))/2) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of ETARAP(forward jet in lab frame) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive di-jet cross section as a function of ETARAP(backward jet in lab frame) and Q**2.. Data are analysed in the Breit frame using the exclusive kT alogrithm.

Inclusive dijet cross section as a function Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of ET and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of the di-jet mass M and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of XI (=XBJ/XP) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of XP and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of X (=XBJ) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of Y (inelasticity) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of ETAPRIME ((ETARAP(P=3)-ETARAP(P=4))/2) and ET.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of ETAPRIME ((ETARAP(P=3)-ETARAP(P=4))/2) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of ETARAP(forward jet in lab frame) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Inclusive di-jet cross section as a function of ETARAP(backward jet in lab frame) and Q**2.. Data are analysed in the Breit frame using the Cambridge jet alogrithm.

Normalised distribution in M(P=4_5) for NC and CC dijet events. M(P=4_5) is the dijet mass.

Normalised distribution in ZP for NC and CC dijet events. ZP corresponds to 0.5*MIN(1-COS(THETA*)) summed over the two jets. THETA* is the polar angle of each parton in the c.m. system of the virtual boson and the incoming parton.

Normalised distribution in XP for NC and CC dijet events. XP is the ratio X/PSI where PSI is the fraction of the protons for momentacarried by the parton entering the hard scattering process.

Normalised distribution in ET(C=FOWARD) for NC and CC dijet events. ET(C=FORWARD) is the transverse energy of the most (non-remnant) forward jet.

Normalised distribution in THETA(C=FORWARD) for NC and CC dijet events. THETA(C=FORWARD) is the polar angle of the most (non-remnant) forward jet.

Normalised distribution in dijet mass for CC and NC events with Q**2 > 5000GeV**2.