The JETSCAPE framework: p+p results

12 Oct 2019  ·  A. Kumar, Y. Tachibana, D. Pablos, C. Sirimanna, R. J. Fries, A. Angerami, S. A. Bass, S. Cao, Y. Chen, J. Coleman, L. Cunqueiro, T. Dai, L. Du, H. Elfner, D. Everett, W. Fan, C. Gale, Y. He, U. Heinz, B. V. Jacak, P. M. Jacobs, 15 S. Jeon, K. Kauder, W. Ke, E. Khalaj, M. Kordell II, T. Luo, A. Majumder, M. McNelis, J. Mulligan, C. Nattrass, D. Oliinychenko, L. -G. Pang, C. Park, J. -F. Paquet, J. H. Putschke, G. Roland, B. Schenke, L. Schwiebert, C. Shen, R. A. Soltz, G. Vujanovic, X. -N. Wang, R. L. Wolpert, Y. Xu, Z. Yang ·

The JETSCAPE framework is a modular and versatile Monte Carlo software package for the simulation of high energy nuclear collisions. In this work we present a new tune of JETSCAPE, called PP19, and validate it by comparison to jet-based measurements in $p+p$ collisions, including inclusive single jet cross sections, jet shape observables, fragmentation functions, charged hadron cross sections, and dijet mass cross sections. These observables in $p+p$ collisions provide the baseline for their counterparts in nuclear collisions. Quantifying the level of agreement of JETSCAPE results with $p+p$ data is thus necessary for meaningful applications of JETSCAPE to A+A collisions. The calculations use the JETSCAPE PP19 tune, defined in this paper, based on version 1.0 of the JETSCAPE framework. For the observables discussed in this work calculations using JETSCAPE PP19 agree with data over a wide range of collision energies at a level comparable to standard Monte Carlo codes. These results demonstrate the physics capabilities of the JETSCAPE framework and provide benchmarks for JETSCAPE users.

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Nuclear Theory High Energy Physics - Experiment Nuclear Experiment