Jet-fragmentation properties inp¯pcollisions at √s=1.8 TeV

Jet fragmentation in pp and PbPb collisions at a centre-of-mass energy of 2.76 TeV per nucleon pair was studied using data collected with the CMS detector at the LHC. Fragmentation functions are constructed using charged-particle tracks with transverse momenta p T > 4 GeV/c for dijet events with a leading jet of p T > 100 GeV/c. The fragmentation functions in PbPb events are compared to those in pp data as a function of collision centrality, as well as dijet-p T imbalance. Special emphasis is placed on the most central PbPb events including dijets with unbalanced momentum, indicative of energy loss of the hard scattered parent partons. The fragmentation patterns for both the leading and subleading jets in PbPb collisions agree with those seen in pp data at 2.76 TeV. The results provide evidence that, despite the large parton energy loss observed in PbPb collisions, the partition of the remaining momentum within the jet cone into high-p T particles is not strongly modified in comparison to that observed for jets in vacuum.

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“…As done in previous measurements at hadron colliders [36], the fragmentation function is presented as a function of the variable…”

Section: Fragmentation Functionsmentioning

confidence: 99%

Measurement of jet fragmentation into charged particles in pp and PbPb collisions at $ \sqrt{{{s_{\mathrm{NN}}}}} = 2.76 $ TeV

Chatrchyan¹,

Khachatryan²,

Sirunyan³

et al. 2012

J. High Energ. Phys.

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120

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“…We note that in real applications, the network should be trained on-line with actual pp jet data where the PQCD jet distribution is known to be correct from a large body of prior experiments [3,4]. With those data, the learning dynamics may train the network to a dierent point in weight space to compensate for the actual eciencies of the detector, the inuence of noise, and physical dierences from the LUND model.…”

Section: Robustness To Softened Jet Spectrummentioning

confidence: 99%

“…However, identifying jets and estimating their total energy in AA reactions poses a practical challenge because of the large background of low-transverse-energy hadrons produced along with the rare jets. Conventional methods of jet analysis developed for pp collisions [3,4] begin to fail in pA collisions [5] due to the enhanced nuclear background and can be expected to fail completely for future applications to nuclear collisions at the relativistic heavy-ion collider (RHIC) and the large hadron collider (LHC) [6]. The question addressed in this paper is whether the powerful pattern-recognition techniques recently developed in the eld of articial neural networks [7] could help overcome this problem.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Neural filters for jet analysis

Dong

Gyulassy

1993

Phys. Rev. E

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We study the eciency of a neural-net lter and deconvolution method for estimating jet energies and spectra in high-background reactions such as nuclear collisions at the relativistic heavy-ion collider and the large hadron collider. The optimal network is shown to be surprisingly close but not identical to a linear high-pass lter. A suitably constrained deconvolution method is shown to uncover accurately the underlying jet distribution in spite of the broad network response. Finally, we show that possible changes of the jet spectrum in nuclear collisions can be analyzed quantitatively, in terms of an eective energy loss with the proposed method.

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“…The same mechanism for the evolution of parton densities, namely soft and collinear parton emission, is responsible for the logarithmic evolution of F (z). Figure 11 shows the evolution of different bins of F (z) as a function of dijet invariant mass (M jj ) from CDF data [79]. The data agree well with a logarithmic evolution with M jj and have a distinct similarity with data from e + e − [80], which are plotted as a function of √ s. M jj appears to be a sensible variable to express this evolution insomuch as it is a measure of the hardness of the scattering, particularly in the central pseudorapidity region.…”

Section: Jet Fragmentationmentioning

confidence: 99%