Geodesic
$J/\psi$ reconstruction in the dimuon decay channel with the CBM experiment for pAu collisions at 30 GeV
Matematičeskoe modelirovanie, Tome 24 (2012) no. 12, pp. 72-77 Cet article a éte moissonné depuis la source Math-Net.Ru

Voir la notice de l'article

The investigation of charmonium production is one of the key goals of the CBM experiment. The study of pAu collisions at 30 GeV beam energy is considered a part of the CBM research program and will be performed in the first phase of FAIR with a start version of the CBM detector at SIS-100. Results of $J/\psi$ reconstruction feasibility studies in dimuon channel in proton-nuclear collisions at SIS-100 energies with the use of KFParticle package are presented. Simulated detector concept includes STS and MuCh detector systems. The algorithm allows to reconstruct $J/\psi$ with an efficiency of 27.16% and the signal to the background ratio of 19.4.
Keywords: CBM, elementary particle reconstruction methods, high energy physics. 
@article{MM_2012_24_12_a12,
     author = {V. P. Akishina},
     title = {$J/\psi$ reconstruction in the dimuon decay channel with the {CBM} experiment for {pAu} collisions at 30 {GeV}},
     journal = {Matemati\v{c}eskoe modelirovanie},
     pages = {72--77},
     year = {2012},
     volume = {24},
     number = {12},
     language = {ru},
     url = {http://geodesic.mathdoc.fr/item/MM_2012_24_12_a12/}
}
TY  - JOUR
AU  - V. P. Akishina
TI  - $J/\psi$ reconstruction in the dimuon decay channel with the CBM experiment for pAu collisions at 30 GeV
JO  - Matematičeskoe modelirovanie
PY  - 2012
SP  - 72
EP  - 77
VL  - 24
IS  - 12
UR  - http://geodesic.mathdoc.fr/item/MM_2012_24_12_a12/
LA  - ru
ID  - MM_2012_24_12_a12
ER  - 
%0 Journal Article
%A V. P. Akishina
%T $J/\psi$ reconstruction in the dimuon decay channel with the CBM experiment for pAu collisions at 30 GeV
%J Matematičeskoe modelirovanie
%D 2012
%P 72-77
%V 24
%N 12
%U http://geodesic.mathdoc.fr/item/MM_2012_24_12_a12/
%G ru
%F MM_2012_24_12_a12
V. P. Akishina. $J/\psi$ reconstruction in the dimuon decay channel with the CBM experiment for pAu collisions at 30 GeV. Matematičeskoe modelirovanie, Tome 24 (2012) no. 12, pp. 72-77. http://geodesic.mathdoc.fr/item/MM_2012_24_12_a12/

[1] Friman B. et al., The CBM Physics Book, Lect. Notes in Phys., 814, 2011, 980 pp. | DOI | Zbl

[2] Kisel I., Zyzak M., CBM Progress Report, Darmstadt, 2010, 78 pp.

[3] CBMROOT framework http://cbmroot.gsi.de

[4] ROOT_An Object-Oriented Data Analysis Framework, User's Guide, 2010

[5] Bass S. et al., Prog. Part. Nucl. Phys., 41 (1998), 255–370 | DOI

[6] Frohlich I. et al., “Pluto: A Monte Carlo Simulation Tool for Hadronic Physics”, PoS ACAT, 2007 (2007), 076

[7] GEANT - Detector Description and Simulation Tool, 1993

[8] The Virtual Monte Carlo (VMC) http://root.cern.ch/drupal/content/vmc

[9] CBM experiment, Technical Status Report, http://www.gsi.de/onTEAM/dokumente/public/DOC-2005-Feb-447.html

[10] Lebedev A., Ososkov G., LIT Track Propagation for CBM, CBM note QCD_CBM_SOFT-note-2008–002, 2008, 8 pp.

[11] Cassing W., Bratkovskaya E. L., “Hadronic and electromagnetic probes of hot and dense nuclear matter”, Phys. Reports, 308 (1999), 65–233 | DOI

[12] Gorbunov S., Kisel I., Reconstruction of Decayed Particles Based on the Kalman Filter, CBM-SOFT-note-2007–003, GSI, Darmstadt, 2007