SPHERICITY distribution.

PLANARITY distribution.

OBLATENESS distribution.

HEAVY JET Mass distribution in the standard scheme definition.

HEAVY JET Mass distribution in the E scheme definition.

LIGHT JET Mass distribution in the standard scheme definition.

JET MASS DIFFERENCE distribution in the standard scheme definition.

TOTAL JET MASS distribution in the standard scheme definition.

TOTAL JET MASS distribution in the E scheme definition.

Wide Jet Broadening (BMAX) distribution.

Narrow Jet Broadening (BMIN) distribution.

Total Jet Broadening (BTOT) distribution.

Jet Broadening Difference (BDIFF) distribution.

C-PARAMETER distribution.

Integrated 2 Jet rates for YCUT=0.04 (Durham, angle ordered Durham and Cambridge alogrithms) and YCUT = 0.8 (JADE alogrithm).

Integrated 3 Jet rates for YCUT=0.04 (Durham, angle ordered Durham and Cambridge alogrithms) and YCUT = 0.8 (JADE alogrithm).

Integrated Jet Cone Energy Fractions (JCEF) for different anglular intervals.

Integrated values of the Energy Energy Correlations (EEC) for different angular intervals.

Integrated values of the Energy Energy Correlations Asymmetry (AEEC) for different angular intervals.

Mean values of Y23.

Mean values of Thrust related observables.

Mean values of the Jet Broadenings.

Mean values of jet masses in the standard definition scheme.

Mean values of jet masses in the E definition scheme.

Mean values of jet masses in the p definition scheme.

Mean values of the C- and D- Parameter variables.

Rapidity distributions (relative to the thrust axis) for c.m. energies from183 to 196 GeV.

Rapidity distributions (relative to the thrust axis) for c.m. energies from200 to 207 GeV.

LN(1/XP) distributions for c.m. energies from 183 to 196 GeV.

LN(1/XP) distributions for c.m. energies from 200 to 207 GeV.

PTIN distributions for c.m. energies from 183 to 196 GeV.

PTIN distributions for c.m. energies from 200 to 207 GeV.

PTOUT distributions for c.m. energies from 183 to 196 GeV.

PTOUT distributions for c.m. energies from 200 to 207 GeV.

1-THRUST distributions for c.m. energies from 183 to 196 GeV.

1-THRUST distributions for c.m. energies from 200 to 207 GeV.

THRUST-MAJOR distributions for c.m. energies from 183 to 196 GeV.

THRUST-MAJOR distributions for c.m. energies from 200 to 207 GeV.

THRUST-MINOR) distributions for c.m. energies from 183 to 196 GeV.

THRUST-MINOR distributions for c.m. energies from 200 to 207 GeV.

Oblateness distributions for c.m. energies from 183 to 196 GeV.

Oblateness distributions for c.m. energies from 200 to 207 GeV.

Wide Jet Broadening (BMAX) distributions for c.m. energies from 183 to 196 GeV.

Wide Jet Broadening (BMAX) distributions for c.m. energies from 200 to 207 GeV.

Total Jet Broadening (BTOT) distributions for c.m. energies from 183 to 196GeV.

Total Jet Broadening (BTOT) distributions for c.m. energies from 200 to 207GeV.

Jet Broadening Difference (BDIFF) distributions for c.m. energies from 183 to 196 GeV.

Jet Broadening Difference (BDIFF) distributions for c.m. energies from 200 to 207 GeV.

C-PARAMETER distributions for c.m. energies from 183 to 196 GeV.

C-PARAMETER distributions for c.m. energies from 200 to 207 GeV.

D-PARAMETER distributions for c.m. energies from 183 to 196 GeV.

D-PARAMETER distributions for c.m. energies from 200 to 207 GeV.

Heavy Jet Mass distributions in the standard scheme definition for c.m. energies from 183 to 196 GeV.

Heavy Jet Mass distributions in the standard scheme definition for c.m. energies from 200 to 207 GeV.

Heavy Jet Mass distributions in the p scheme definition for c.m. energies from 183 to 196 GeV.

Heavy Jet Mass distributions in the p scheme definition for c.m. energies from 200 to 207 GeV.

Heavy Jet Mass distributions in the E scheme definition for c.m. energies from 183 to 196 GeV.

Heavy Jet Mass distributions in the E scheme definition for c.m. energies from 200 to 207 GeV.

Light Jet Mass distributions in the standard definition for c.m. energies from 183 to 196 GeV.

Light Jet Mass distributions in the standard definition for c.m. energies from 200 to 207 GeV.

Jet Mass Difference distributions from c.m.energies from 183 to 196 GeV.

Jet Mass Difference distributions from c.m.energies from 200 to 207 GeV.

Sphericity distributions for c.m.energies from 183 to 196 GeV.

Sphericity distributions for c.m.energies from 200 to 207 GeV.

Planarity distributions for c.m.energies from 183 to 196 GeV.

Planarity distributions for c.m.energies from 200 to 207 GeV.

Aplanarity distributions for c.m.energies from 183 to 196 GeV.

Aplanarity distributions for c.m.energies from 200 to 207 GeV.

The proton plus antiproton fraction and differential production rate per hadronic Z0 decay.

Differential production rates of charged pions per Z0 decay into light (u,d,s) and c and b quarks. The errors are combined statistical and systematic.

Differential production rates of charged kaons per Z0 decay into light (u,d,s) and c and b quarks. The errors are combined statistical and systematic.

Differential production rates of charged protons plus antiprotons per Z0 decay into light (u,d,s) and c and b quarks. The errors are combined statistical and systematic.

Differential production rates of stable charged particles per Z0 decay intolight (u,d,s) and c and b quarks. The errors are combined statistical and syste matic.

Differential production rate for positive and negative charged pions into light quark jets from hadronic Z0 decays. Also shown are the normalization differences. The ratios are defined as:-. R(Q=PI+)=(1/2N(Q=Z0))*D(N(QUARK --> PI+) + N(QUARKBAR --> PI-))/DX. R(Q=PI-)=(1/2N(Q=Z0))*D(N(QUARK --> PI-) + N(QUARKBAR --> PI+))/DX.

Differential production rate for positive and negative charged kaons into light quark jets from hadronic Z0 decays. Also shown are the normalization differences. The ratios are defined as:-. R(Q=K+)=(1/2N(Q=Z0))*D(N(QUARK --> K+) + N(QUARKBAR --> K-))/DX. R(Q=K-)=(1/2N(Q=Z0))*D(N(QUARK --> K-) + N(QUARKBAR --> K+))/DX.

Differential production rate for positive and negative protons into light quark jets from hadronic Z0 decays. Also shown are the normalization differences.The ratios are defined as:-. R(Q=P+)=(1/2N(Q=Z0))*D(N(QUARK --> P+) + N(QUARKBAR --> PBAR))/DX. R(Q=PBAR)=(1/2N(Q=Z0))*D(N(QUARK --> PBAR) + N(QUARKBAR --> P+))/DX.

The inclusive charged particle differential cross section.

The K0 + K0BAR inclusive differential cross section. The last line in the table is the integral over the full X range of the measurement.. There is an additional 3.4 PCT normalization error (included in the integral).

The LAMBDA + LAMBDABAR inclusive differential cross section. The last line in the table is the integral over the full X range of the measurement.. There is an additional 3.4 PCT normalization error (included in the integral).

No description provided.

The K*0 + K*BAR0 inclusive differential cross section. The last line in the table is the integral over the full X range of the measurement.. There is an additional 3.4 PCT normalization error (included in the integral).

The PHI meson inclusive differential cross section. The last line in the table is the integral over the full X range of the measurement.. There is an additional 3.4 PCT normalization error (included in the integral).

Measured differential cross section for the production of charged pions perZ0 decay into light, charm and bottom quarks separately. The errors given are t he sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

The ratios of light to heavy quark production of charged pions. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

Measured differential cross section for the production of charged kaons perZ0 decay into light, charm and bottom quarks separately. The errors given are t he sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

The ratios of light to heavy quark production of charged kaons. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

Measured differential cross section for the production of neutral K* mesonsper Z0 decay into light, charm and bottom quarks separately. The errors given a re the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

The ratios of light to heavy quark production of neutral K* mesons. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

Measured differential cross section for proton/antiproton production per Z0decay into light, charm and bottom quarks separately. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours arenot included.

The ratios of light to heavy quark production of proton/antiprotons. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to thethree flavours are not included.

Measured differential cross section for lambda/antilambda production per Z0decay into light, charm and bottom quarks separately. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours arenot included.

The ratios of light to heavy quark lambda/lambdabar production. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

Measured differential cross section for the production of neutral kaons perZ0 decay into light, charm and bottom quarks separately. The errors given are t he sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

The ratios of light to heavy quark for neutral kaon production. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

Measured differential cross section for phi meson production per Z0 decay into light, charm and bottom quarks separately. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from theunfolding procedure. Systematic errors common to the three flavours are not inc luded.

The ratios of light to heavy quark for phi meson production. The errors given are the sum in quadrature of the statistical errors and those systematic errors arising from the unfolding procedure. Systematic errors common to the three flavours are not included.

Corrected total cross sections per hadronic Z decay, and per decay into light, CQ or BQ primary flavour separately. The errors given are the sum in quadrature of experimental and extrapolation uncertainties.

Differences of total cross sections per hadronic Z decay, between CQ (and BQ) and light quarks decays. The errors given are the sum in quadrature of experimental and extrapolation uncertainties.

The differential cross sections for the production of positive and negativepions in light (u,d,s) quark jets from hadronic Z0 decays. The errors given are the sum in quadrature of statistical errors and those systematic errors arising from the light quark tagging and unfolding procedure.. Here QUARK (QUARKBAR) means any light quark (antiquark).

The normalized difference between the differential cross sections for the production of positive and negative pions in light (u,d,s) quark jets from hadronic Z0 decays. The errors given are the sum in quadrature of statistical errors and those systematic errors arising from the light quark tagging and unfolding procedure.. Here QUARK (QUARKBAR) means any light quark (antiquark).

The differential cross sections for the production of neutral K* and K*BAR mesons in light (u,d,s) quark jets from hadronic Z0 decays. The errors given arethe sum in quadrature of statistical errors and those systematic errors arising from the light quark tagging and unfolding procedure.. Here QUARK (QUARKBAR) means any light quark (antiquark).

The normalized difference between the differential cross sections for the production of neutral K* and K*BAR mesons in light (u,d,s) quark jets from hadronic Z0 decays. The errors given are the sum in quadrature of statistical errors and those systematic errors arising from the light quark tagging and unfolding procedure.. Here QUARK (QUARKBAR) means any light quark (antiquark).

The differential cross sections for the production of positive and negativeK mesons in light (u,d,s) quark jets from hadronic Z0 decays. The errors given are the sum in quadrature of statistical errors and those systematic errors arising from the light quark tagging and unfolding procedure.. Here QUARK (QUARKBAR) means any light quark (antiquark).

The normalized difference between the differential cross sections for the production of positive and negative kaons in light (u,d,s) quark jets from hadronic Z0 decays. The errors given are the sum in quadrature of statistical errors and those systematic errors arising from the light quark tagging and unfolding procedure.. Here QUARK (QUARKBAR) means any light quark (antiquark).

The differential cross sections for the production of proton and antiprotons in light (u,d,s) quark jets from hadronic Z0 decays. The errors given are the sum in quadrature of statistical errors and those systematic errors arising fromthe light quark tagging and unfolding procedure.. Here QUARK (QUARKBAR) means any light quark (antiquark).

The normalized difference between the differential cross sections for the production of protons and antiprotons in light (u,d,s) quark jets from hadronic Z0 decays. The errors given are the sum in quadrature of statistical errors and those systematic errors arising from the light quark tagging and unfolding procedure.. CCT. = Here QUARK (QUARKBAR) means any light quark (antiquark).

The differential cross sections for the production of lambdas and antilambdas in light (u,d,s) quark jets from hadronic Z0 decays. The errors given are thesum in quadrature of statistical errors and those systematic errors arising fro m the light quark tagging and unfolding procedure.. Here QUARK (QUARKBAR) means any light quark (antiquark).

The normalized difference between the differential cross sections for the production of protons and antiprotons in light (u,d,s) quark jets from hadronic Z0 decays. The errors given are the sum in quadrature of statistical errors and those systematic errors arising from the light quark tagging and unfolding procedure.. Here QUARK (QUARKBAR) means any light quark (antiquark).

Current hemisphere fragmentation as a function of Q for the XP range 0.05 to 0.10, to show scaling violations.

Current hemisphere fragmentation as a function of Q for the XP range 0.10 to 0.20, to show scaling violations.

Current hemisphere fragmentation as a function of Q for the XP range 0.20 to 0.30, to show scaling violations.

Current hemisphere fragmentation as a function of Q for the XP range 0.30 to 0.40, to show scaling violations.

Current hemisphere fragmentation as a function of Q for the XP range 0.40 to 0.50, to show scaling violations.

Current hemisphere fragmentation as a function of Q for the XP range 0.40 to 0.50, to show scaling violations.

The average charged multiplicity, and the peak and width of the fragmentation function (in LN(1/XP)) as a function of the mean Q, for the total hemisphere of the Breit frame without the energy flow selection discussed in the text of the paper.

The average charged multiplicity, and the peak and width of the fragmentation function (in LN(1/XP)) as a function of the mean Q, with the energy flow selection, obtained from the Total Current Hemisphere sample.

Invariant charged hadron energy spectrum in the current hemisphere for a mean Q of 5.5. Results are given for all the data and for the energy flow selecteddata.

Invariant charged hadron energy spectrum in the current hemisphere for a mean Q of 19.6. Results are given for all the data and for the energy flow selected data.

Invariant charged hadron energy spectrum in the current hemisphere for the Q**2 range 12 to 15 GeV**2.

Invariant charged hadron energy spectrum in the current hemisphere for the Q**2 range 15 to 20 GeV**2.

Invariant charged hadron energy spectrum in the current hemisphere for the Q**2 range 20 to 40 GeV**2.

Invariant charged hadron energy spectrum in the current hemisphere for the Q**2 range 40 to 60 GeV**2.

Invariant charged hadron energy spectrum in the current hemisphere for the Q**2 range 60 to 80 GeV**2.

Invariant charged hadron energy spectrum in the current hemisphere for the Q**2 range 80 to 100 GeV**2.

The probability per event of observing a charged hadronic multiplicity of (ULT) in the current hemisphere of the Breit frame (at Q = 4.15 GeV, X=0.00126).

The probability per event of observing a charged hadronic multiplicity of MULT in the current hemisphere of the Breit frame (at Q = 4.53 GeV, X=0.00255).

The probability per event of observing a charged hadronic multiplicity of MULT in the current hemisphere of the Breit frame (at Q = 6.20 GeV, X=0.00158).

The probability per event of observing a charged hadronic multiplicity of MULT in the current hemisphere of the Breit frame (at Q = 7.04 GeV, X=0.00410).

The probability per event of observing a charged hadronic multiplicity of MULT in the current hemisphere of the Breit frame (at Q = 14.5 GeV, X=0.00682).

The probability per event of observing a charged hadronic multiplicity of MULT in the current hemisphere of the Breit frame (at Q = 17.3 GeV, X=0.00234).

Charged particle Thrust(minor) distribution.

Charged particle Two-jet resolution variable, Y3 distribution.

Charged particle Heavy Jet Mass distribution.

Charged particle C-Parameter distribution.

Charged particle Oblateness distribution.

Charged particle XP distribution.

Charged particle rapidity distribution.

Charged particle PTIN distribution.

Charged particle PTOUT distribution.

Measure n-jet rates using the Durham cluster algorithm as a function of thejet-resolution parameter YCUT.

Measure n-jet rates using the Durham cluster algorithm as a function of thejet-resolution parameter YCUT.

Measure n-jet rates using the Durham cluster algorithm as a function of thejet-resolution parameter YCUT.

Measure n-jet rates using the Durham cluster algorithm as a function of thejet-resolution parameter YCUT.

Charged particle inclusive distribution of -LN(1/X).

Unfolded charged particle multiplicity distribution giving the probability to have a hadronic Z0 decay with N charged particles.

Values of the mean values of the leading moments of the charged particle multiplicity distribution. R2 is the second binomial moment defined as MEAN(N*(N-1))/MULT**2.

Unfolded values of the the mean multiplicity and dispersion of the multiplicity distributions integaretd over the rapidity region -0.5 to 0.5.

Unfolded values of the the mean multiplicity and dispersion of the multiplicity distributions integrated over the rapidity region -1.0 to 1.0.

Unfolded values of the the mean multiplicity and dispersion of the multiplicity distributions integrated over the rapidity region -1.5 to 1.5.

Unfolded values of the the mean multiplicity and dispersion of the multiplicity distributions integrated over the rapidity region -2.0 to 2.0.

Unfolded values of the the mean multiplicity and dispersion of the multiplicity distribution integrated over the full rapidity region.

Differential cross sections for the inclusive production of PI+-. Additional 3pct systematic uncertainty.

Differential cross sections for the inclusive production of K+-. Additionalsystematic uncertainty 3% above and 5% below X = 0.010.

Differential cross sections for the inclusive production of P PBAR. Additional systematic uncertainty 3% above and 5% below X = 0.018.

Measured inclusive photon cross section. Errors contain both statistical and systematic uncertainties.

Measured differential cross section for PI0 production.

Measured fragmentation function at the ETA meson. Additional 6pct systematic error.

Measured fragmentation function at the ETAPRIME meson. Additional 8pct systematic error.

Inclusive K0 spectrum. Additional 2pct normalization error.

Inclusive LAMBDA spectrum. Additional 4pct normalization error.

Fragmentation distribution for XI production.

Fragmentation distribution for SIGMA(1385) production.

Fragmentation distribution for XI(1530) production.

Differential cross section for RHO0 production.

Differential cross section for OMEGA production.

Differential cross section for K*0 production.

Differential cross section for PHI production.

Differential cross section for K*0 production as a function of the transverse momentum with respect to the Thrust axis.

Differential cross section for PHI production as a function of the transverse momentum with respect to the Thrust axis.

Fragmentation distribution for K*+- production.

Mean Multiplicities. Where a second systematic error is given, this is due to the uncertainty in the extrapolation to X = 0. Note that the ETA and ETAPRIMEvalues are for X > 0.1.

Transverse momentum PTOUT w.r.t. the Shericity axis. For the first table Sphericity axis definition is from seen charged particles corrected to final state particles. For the second table Sphericity axis definition is from seen charged plus neutral particles corrected to final state charged plus neutral particles.

Rapidity, YT, w.r.t. the Thrust axis. For the first table Thrust axis definition is from seen charged particles corrected to final state particles. For the second table Thrust axis definition is from seen charged plus neutral particles corrected to final state charged plus neutral particles.

Rapidity, YS, w.r.t. the Sphericity axis. For the first table Sphericity axis definition is from seen charged particles corrected to final state particles. For the second table Sphericity axis definition is from seen charged plus neutral particles corrected to final state charged plus neutral particles.

Scaled momentum distribution, XP. Corrected to final state charged particles.

LN(1/XP) distribution. Corrected to final state charged particles.

Mean PTOUT V XP. Corrected to final state charged particles.

Mean PT V XP. Corrected to final state charged particles.

1-Thrust distribution. Corrected to final state particles.

Thrust Major distribution. Corrected to final state particles.

Thrust Minor distribution. Corrected to final state particles.

Oblateness distribution. Corrected to final state particles.

Sphericity distribution. Corrected to final state particles.

Aplanarity distribution. Corrected to final state particles.

Planarity distribution. Corrected to final state particles.

C-Parameter distribution. Corrected to final state particles.

D-Parameter distribution. Corrected to final state particles.

Heavy-Hemisphere-Mass distribution. Corrected to final state particles.

Light-Hemisphere-Mass distribution. Corrected to final state particles.

Difference in Hemisphere Masses. Corrected to final state particles.

Wide Hemisphere Broadening, BMAX. Corrected to final state particles.

Narrow Hemisphere Broadening, BMIN. Corrected to final state particles.

Total Hemisphere Broadening, BSUM. Corrected to final state particles.

Difference of the Hemisphere Broadening, BDIFF. Corrected to final state particles.

Differential 2-jet rate for the Durham Algorithm. Corrected to final state particles. YCUT is the jet finding cutt-off parameter.

Differential 2-jet rate for the JADE Algorithm. Corrected to final state particles. YCUT is the jet finding cutt-off parameter.

Differential 3-jet rate for the Durham Algorithm. Corrected to final state particles. YCUT is the jet finding cutt-off parameter.

Differential 3-jet rate for the JADE Algorithm. Corrected to final state particles. YCUT is the jet finding cutt-off parameter.

Differential 4-jet rate for the Durham Algorithm. Corrected to final state particles. YCUT is the jet finding cutt-off parameter.

Differential 4-jet rate for the JADE Algorithm. Corrected to final state particles. YCUT is the jet finding cutt-off parameter.

Energy-Energy Correlation EEC. Corrected to final state particles.

Asymmetry of the Energy-Energy Correlation AEEC. Corrected to final state particles.

Charged particle multiplicity compiled from current LEP I data.

Compilation of multiplicities of pseudoscalar mesons from current LEP I data.

Compilation of multiplicities of scalar mesons from current LEP I data.

Compilation of multiplicities of vector mesons from current LEP I data.

Compilation of multiplicities of tensor mesons from current LEP I data.

Compilation of multiplicities of baryons from current LEP I data.

LOG(1/XP) distribution for K0 production.. Data read from plot.

LOG(1/XP) distribution for K+- production.. Data read from plot.

XP distribution for K*(892)0 production.. Data read from plot.

XP distribution for K*(892)+- production.. Data read from plot.

XE distribution for PHI production.. Data read from plot.

XP distribution for RHO0 production.. Data read from plot.

XP distribution for F0(980) production.. Data read from plot.

XP distribution for F2(1270) production.. Data read from plot.

LOG(1/XP) distribution for P production.. Data read from plot.

LOG(1/XP) distribution for LAMBDA production.. Data read from plot.

XP distribution for P production.. Data read from plot.

XP distribution for LAMBDA production.. Data read from plot.

XP distribution for XI+- production.. Data read from plot.

XP distribution for DEL++ production.. Data read from plot.

XP distribution for SIGMA(1385)+ production.. Data read from plot.

XP distribution for XI(1530)0 production.. Data read from plot.