Extrapolation to LEP 2 Energies

A question of interest for LEP 2 is that of how well the characteristics of QCD events are understood at large energies. By QCD events, it is here meant those that are produced through the s-channel decay of a Z into quark and gluon jets. This question is of interest because WW events lead to multi-jet states for which one of the principal backgrounds will be QCD events, because QCD events will also form a principal source of background for higgs, chargino and other particle searches, and because QCD events will be interesting in their own right as a means to test perturbation theory in a regime with particularly small hadronization uncertainties. The principal tools to test how well QCD event characteristics are understood are Monte Carlo generators. The main generators, ARIADNE, COJETS, HERWIG and PYTHIA, have been tuned by the LEP experiments or by the Monte Carlo authors to describe global features of hadronic Z data. In many cases, the generators have proven able to describe detailed features of these data as well. It is thus relevant to extrapolate the predictions of the QCD generators to LEP 2 energies and to compare their level of agreement for distributions likely to be of importance at LEP 2. In this section, such an extrapolation and comparison is presented.

For this study, members of each of the LEP experiments generated Monte Carlo event samples at =175 GeV using parameter sets determined within their Collaboration. The Monte Carlo parameter sets used at LEP 1 are continually revised in order to yield as accurate a description of the Z data as possible. Therefore, the parameter sets employed for this study do not necessarily represent official versions which will be published by the Collaborations. The parameter sets used for ARIADNE, HERWIG and PYTHIA are given in tables 3--5. For COJETS, L3 and OPAL results were made available using the parameter values given in table 6. There are numerous parameters and strategies involved in the optimization of the parameters. Comparison of the results obtained using the parameter sets of the different Collaborations therefore provides a systematic check of effects associated with the optimization choice. Samples of 100,000 events were generated without initial-state photon radiation or detector simulation, treating all charged and neutral particles with mean lifetimes greater than s as stable.

  
Table 3: Optimized parameter sets for ARIADNE, version 4.06 (for ALEPH, version 4.05), from the LEP Collaborations. The parameters listed are those which were changed from their default values by at least one of the groups. The ARIADNE events were generated using PYTHIA version 5.7 to describe the hadronization and hadron decays. The DELPHI Collaboration implements its own procedure to specify the relative rate at which mesons are produced in different multiplets [9], in place of the PYTHIA parameters PARJ(11)-PARJ(17).

  
Table: Optimized parameter sets for HERWIG, version 5.8, from the LEP Collaborations. The parameters listed are those which were changed from their default values by at least one of the groups.

  
Table 5: Optimized parameter sets for PYTHIA, version 5.7, from the LEP Collaborations. The parameters listed are those which were changed from their default values by at least one of the groups. The DELPHI Collaboration implements their own procedure to specify the relative rate at which mesons are produced in different multiplets [9], in place of the PYTHIA parameters PARJ(11)--PARJ(17).

  
Table 6: Optimized parameter sets for COJETS, version 6.23, from the L3 and OPAL Collaborations. The parameters listed are those which were changed from their default values by at least one of the groups.

The following distributions were examined using charged particles only:

• charged particle multiplicity, ,
• scaled particle momentum, ,
• component of particle momentum in the event plane, , and
• component of particle momentum out of the event plane, .

The following distributions were examined using both charged and neutral particles:

• Thrust, T [114],
• Thrust major, [115],
• Thrust minor, [115],
• jet rates defined using the jet finder [116],
• normalized heavy jet mass for events divided into hemispheres by the plane perpendicular to the Thrust axis, [117],
• normalized difference between the heavy and light jet masses, ,
• total jet broadening, [118],
• wide jet broadening, [118],
• Sphericity, S [119],
• Aplanarity, A [120],
• the modified Nachtmann-Reiter four-jet angular variable, [121], with four-jet events defined using the jet finder with =0.01, and
• the cosine of the angle between the two lowest energy jets in the four-jet events, .

The results for , and as a function of are shown in Fig. 7.

  
Figure: The mean values of , Thrust and predicted by ARIADNE, COJETS, HERWIG and PYTHIA as a function of in comparison with measurements from PEP, PETRA, TRISTAN and LEP 1. The LEP 2 point is indicative only, based on the PYTHIA prediction. The total uncertainty expected at LEP 2 assuming QCD events is smaller than the symbol size.

For those cases in which the results of at least three Collaborations are similar to each other, the Monte Carlo predictions are shown as shaded or hatched bands. The widths of the bands show the maximum deviations between the results found by the different Collaborations. The widths of the bands are generally much larger than the statistical uncertainties. In a few cases, the Monte Carlo prediction obtained by one of the Collaborations differs significantly from those obtained by the other three groups and is shown as a separate curve. The COJETS predictions are likewise shown as separate curves for purposes of clarity. The results found by the four LEP experiments are labelled A, D, L and O in the figure legends.

Representative measurements from PEP, PETRA, TRISTAN and LEP 1 are included in Fig. 7. For =175 GeV, an indicative ``data point'' is also shown, which is taken to be equal to the mean of the PYTHIA predictions from the four groups. The size of the symbol for the LEP 2 point is larger than the statistical uncertainty for QCD events. Systematic terms were generally found to dominate the statistical ones for the experimental measurements shown in Fig. 7. The total experimental uncertainties at 175 GeV can therefore be expected to be comparable to those found for the LEP 1 data.

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Figure 8: Comparison of the predictions of QCD event generators at =175 GeV.

From the distribution of versus (Fig. 7(a)), it is seen that, with the exception of the L3 ARIADNE curve, the predictions of ARIADNE, HERWIG and PYTHIA are similar. The widths of the ARIADNE, HERWIG and PYTHIA bands are narrow for energies at and below the Z mass, showing that the results from the four Collaborations are in close agreement (with the exception of the L3 curve for ARIADNE). For energies above about 150 GeV, the HERWIG band becomes broader, indicating that there is some divergence in the predictions obtained by the different groups. From Fig. 7(a) it is also seen that COJETS predicts a substantially larger value of than the other models for energies above the Z mass. This difference is suggestive of coherence effects in the parton shower, which are absent in COJETS but present in the other three models. Coherence reduces the mean soft gluon multiplicity in the parton shower. It is generally expected that coherence will lead to a reduction in the mean hadron multiplicity as well. Thus, a measurement of at LEP 2 could help to establish the existence of coherence phenomena in the data.

Figs. 7(b)--(d) show the corresponding distributions for the and variables. Again, ARIADNE, HERWIG and PYTHIA are seen to exhibit similar behavior. COJETS agrees well with the other models for T, but lies below them for and above them for in the LEP 2 energy range. Thus the jets from COJETS are less oblate than those from ARIADNE, HERWIG or PYTHIA. (The Oblateness O of an event is given by .) The differences between COJETS and the other three models become larger as increases.

  
Figure 9: Comparison of the predictions of QCD event generators at =175 GeV.

In Fig. 8, the Monte Carlo predictions for , , and at 175 GeV are shown. The corresponding results for T, , and , for , , and , and for , and are shown in Figs. 9, 10, and 11, respectively. Overall, the models are seen to be in general agreement with each other. Some of the more notable exceptions to this agreement are discussed below.

• A striking difference is observed between COJETS and the other models for the and distributions (Figs. 8(a) and (c)). Smaller but visible differences are observed between COJETS and the other models for a number of the other distributions as well. At the Z mass, these differences between COJETS and the other models are either not present or are much smaller. This implies that the energy scaling behavior of COJETS differs from that of ARIADNE, HERWIG and PYTHIA.
• For HERWIG, the distribution is much harder using the L3 parameter set than it is using the parameter sets of the other Collaborations (Fig. 8(b)). This feature is also observed at the Z energy. The primary reason for this difference between L3 and the other groups is the different treatment of the parameter CLSMR (see table 4).
• From Fig. 9(d), it is seen that the three-jet rate from PYTHIA is significantly larger than that of the other models for values below about 0.02. Correspondingly, the two jet rate from PYTHIA is smaller. This difference is also observed at =91 GeV. From this same figure, COJETS is seen to predict a three-jet rate which is smaller than that of the other models: this last difference is not observed at LEP 1 energies.
• COJETS exhibits a clear deviation with respect to the predictions of the other models for the jet mass distributions, and (Figs. 10(a) and (b)). Less of a deviation is present for the jet broadening variables, and (Figs. 10(c) and (d)). This suggests that these last two variables may be less subject to uncertainties related to the modelling of QCD and hadronization than the first two variables.
• COJETS and HERWIG are seen to exhibit a somewhat flatter distribution in than ARIADNE and PYTHIA (Fig. 11(c)).

The general conclusion that can be drawn from this study is that there is relatively little uncertainty in the predictions of QCD generators for event characteristics at LEP 2. Such basic features of events as charged multiplicity, Thrust and Oblateness are described in an almost identical manner by ARIADNE, HERWIG and PYTHIA. Only COJETS deviates significantly from the predictions of the other models. On the other hand, there is modest disagreement between the models for variables which require use of a jet finding algorithm: (Fig. 9(d)) and (Fig. 11(c)). This could have some implication for the W mass determination based on the reconstruction of jets.

  
Figure 10: Comparison of the predictions of QCD event generators at =175 GeV.

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Figure 11: Comparison of the predictions of QCD event generators at =175 GeV.