{"title":"Simulation of the Large Hadrons Collisions Using Monte Carlo Tools","authors":"E. Al Daoud","volume":123,"journal":"International Journal of Mathematical and Computational Sciences","pagesStart":94,"pagesEnd":98,"ISSN":"1307-6892","URL":"https:\/\/publications.waset.org\/pdf\/10006544","abstract":"In many cases, theoretical treatments are available for models for which there is no perfect physical realization. In this situation, the only possible test for an approximate theoretical solution is to compare with data generated from a computer simulation. In this paper, Monte Carlo tools are used to study and compare the elementary particles models. All the experiments are implemented using 10000 events, and the simulated energy is 13 TeV. The mean and the curves of several variables are calculated for each model using MadAnalysis 5. Anomalies in the results can be seen in the muons masses of the minimal supersymmetric standard model and the two Higgs doublet model.","references":"[1]\tA. Denner, S. Dittmaier, L. Hofer, \"Collier: a fortran-based Complex One-Loop Library in Extended Regularizations\" . FR-PHENO-2016-003, ICCUB-16-016 arXiv:1604.06792. 2016.\r\n[2]\tR. Y. Rubinstein and D. P. Kroese, Simulation and the Monte Carlo Method. John Wiley & Sons, New York, second edition, 2007.\r\n[3]\tD. P. Kroese, T. Taimre, and Z. I. Botev, Handbook of Monte Carlo Methods. John Wiley & Sons, New York, 2011.\r\n[4]\tT. Peraro, \"Ninja: Automated Integrand Reduction via Laurent Expansion for One-Loop Amplitudes,\"Comput. Phys. Commun.Vol. 185, pp 2771\u20132797, 2014.\r\n[5]\tH. van Deurzen, G. Luisoni, P. Mastrolia, E. Mirabella, G. Ossola, et al., \"Multi-leg One-loop Massive Amplitudes from Integrand Reduction via Laurent Expansion,\"JHEP 1403, arXiv:1312.6678, 2014.\r\n[6]\tK. Hamilton, P. Nason, E. Re, and G. Zanderighi, \"NNLOPS simulation of Higgs boson production,\"JHEP 1310, arXiv:1309.0017, 2013.\r\n[7]\tJ. P. Guillet, G. Heinrich, and J. F. von Soden-Fraunhofen, \"Tools for NLO automation: extension of the golem95C integral library,\" Comput. Phys. Commun.Vol. 185, pp 1828\u20131834, 2014.\r\n[8]\tC. Duhr and B. Fuks \"A superspace module for the FeynRules package,\" Comput.Phys.Commun., vol. 182, pp 2404-2426, 2011.\r\n[9]\tD. Neil and C. Duhr \"FeynRules - Feynman rules made easy,\" Comput.Phys.Commun.vol. 180, pp 1614-1641, 2009.\r\n[10]\tC. Degrades et al., \"UFO\u2013The Universal FeynRules Output,\" Comput. Phys. Commun., vol. 183, pp 1201-1214, 2012.\r\n[11]\tJ. Alwall et al., \"The automated computation of tree-level and next-to-leading order differential cross sections, and their matching to parton shower simulations\", JHEP 1407, arXiv:1405.0301, 2014.\r\n[12]\tJ. Alwall, M. Herquet, F. Maltoni, O. Mattelaer, and T. Stelzer, \" MadGraph 5: Going Beyond,\"JHEP 1106, arXiv:1106.0522, 2011.\r\n[13]\tE.Conte, B. Fuks, G. Serret\"MadAnalysis 5, a user-friendly framework for collider phenomenology\". IPHC-PHENO-12-06, arXiv:1206.1599, 2012.","publisher":"World Academy of Science, Engineering and Technology","index":"Open Science Index 123, 2017"}