Inclusive, prompt and non-prompt J/ψ production at mid-rapidity in Pb-Pb collisions at s N N = 2.76 $$ \sqrt{s_{\mathrm{NN}}}=2.76 $$ TeV

Adam, J.; Adamová, D.; Aggarwal, M. M.; Rinella, G. Aglieri; Agnello, M.; Agrawal, N.; Ahammed, Z.; Ahn, S. U.; Aimo, I.; Aiola, S.; Ajaz, M.; Akindinov, A.; Alam, Sk Noor; Aleksandrov, D.; Alessandro, B.; Alexandre, D.; Molina, R. Alfaro; Alici, A.; Alkin, A.; Alme, J.; Alt, T.; Altinpinar, S.; Altsybeev, I.; Prado, C. Alves Garcia; Andrei, C.; Andronic, A.; Anguelov, V.; Anielski, J.; Antičić, T.; Antinori, F.; Antonioli, P.; Aphecetche, L.; Appelshäuser, H.; Arcelli, S.; Armesto, N.; Arnaldi, R.; Arsene, I. C.; Arslandok, M.; Audurier, B.; Augustinus, A.; Averbeck, R.; Azmi, M. D.; Bach, M.; Badalà, A.; Baek, Y. W.; Bagnasco, S.; Bailhache, R.; Bala, R.; Baldisseri, A.; Pedrosa, F. Baltasar Dos Santos; Baral, R. C.; Barbano, Anastasia Maria; Barbera, R.; Barile, F.; Barnaföldi, G. G.; Barnby, Lee Stuart; Barret, V.; Bartalini, P.; Barth, K.; Bartke, J.; Bartsch, E.; Basile, M.; Bastid, N.; Basu, S.; Bathen, B.; Batigne, G.; Camejo, A. Batista; Batyunya, B.; Batzing, P. C.; Bearden, I. G.; Beck, H.; Bedda, C.; Behera, N. K.; Belikov, I.; Bellini, F.; Martinez, H.; Bellwied, R.; Belmont, R.; Belmont‐Moreno, E.; Belyaev, V.; Bencédi, G.; Beolè, S.; Berceanu, I.; Bercuci, A.; Berdnikov, Y.; Berényi, D.; Bertens, R. A.; Berzano, D.; Betev, L.; Bhasin, A.; Bhat, I. R.; Bhati, A. K.; Bhattacharjee, B.; Bhom, J.; Bianchi, L.; Bianchi, N.; Bianchin, C.; Bielčík, J.; Bielčíková, J.; Bilandzic, A.; Biswas, R.; Biswas, S.; Bjelogrlic, S.; Blanco, F.; Blau, D.; Blume, C.; Bock, F.; Bogdanov, A.; Bøggild, H.; Boldizsár, L.; Bombara, M.; Book, J.; Borel, H.; Borissov, A.; Borri, M.; Bossù, F.; Botje, M.; Botta, E.; Böttger, S.; Braun‐Munzinger, P.; Bregant, M.; Breitner, T.; Broker, T. A.; Browning, T. A.; Broz, M.; Brücken, E.; Bruna, E.; Bruno, G. E.; Budnikov, D.; Buesching, H.; Bufalino, S.; Bunčić, P.; Busch, O.; Buthelezi, Z.; Buxton, J. T.; Caffarri, D.; Cai, X.; Caines, H.; Diaz, L. Calero; Caliva, A.; Villar, E. Calvo; Camerini, P.; Carena, F.; Carena, W.; Castellanos, J. Castillo; Castro, A.; Casula, Ester Anna Rita; Cavicchioli, C.; Sànchez, C. Ceballos; Cepila, J.; Cerello, P.; Cerkala, J.; Chang, B.; Chapeland, S.; Chartier, M.; Charvet, J. L.; Chattopadhyay, S.; Chelnokov, V.; Cherney, M.; Cheshkov, C.; Cheynis, B.; Barroso, V. Chibante; Chinellato, D. D.; Chochula, P.; Choi, K.; Chojnacki, M.; Choudhury, S.; Christakoglou, P.; Christensen, Christian Holm; Christiansen, P.; Chujo, T.; Chung, S. U.; Zhang, Chunhui; Cicalò, C.; Cifarelli, L.; Cindolo, F.; Cleymans, J.; Colamaria, F.; Colella, D.; Collu, A.; Colocci, M.; Balbastre, G. Conesa; Valle, Z. Conesa del; Connors, M.; Contreras, J. G.; Cormier, Thomas Michael; Morales, Y. Corrales; Maldonado, I. Cortés; Cortese, P.; Cosentino, M. R.; Costa, F.; Crochet, P.; Albino, R. 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G.; Polichtchouk, B.; Poljak, N.; Poonsawat, W.; Pop, A.; Porteboeuf-Houssais, S.; Porter, J.; Pospı́šil, J.; Prasad, Sidharth Kumar; Preghenella, R.; Prino, F.; Pruneau, C.; Pshenichnov, I.; Puccio, M.; Puddu, G.; Pujahari, P. R.; Punin, V.; Putschke, J.; Qvigstad, H.; Rachevski, A.; Raha, S.; Rajput, S.; Rak, J.; Rakotozafindrabe, A.; Ramello, L.; Raniwala, R.; Raniwala, S.; Rasanen, Sami Sakari; Rascanu, B. T.; Rathee, D.; Read, Kenneth Francis; Réal, J. S.; Redlich, K.; Reed, R.; Rehman, A.; Reichelt, P.; Reidt, F.; Ren, X.; Renfordt, R.; Reolon, A. R.; Reshetin, A.; Rettig, F.; Revol, J.-P.; Reygers, K.; Riabov, V.; Ricci, R. A.; Richert, T.; Richter, Matthias; Riedler, P.; Riegler, W.; Riggi, F.; Ristea, C.; Rivetti, A.; Rocco, E.; Cahuantzi, M. Rodríguez; Manso, A. Rodriguez; Røed, K.; Rogochaya, E.; Røhr, D.; Röhrich, D.; Romita, R.; Ronchetti, F.; Ronflette, L.; Rosnet, P.; Rossi, A.; Roukoutakis, F.; Roy, A.; Roy, C.; Roy, P.; Montero, A.J. 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doi:10.1007/jhep07(2015)051

Cited by 60 publications

(64 citation statements)

References 92 publications

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“…In the p T interval 3 < p T < 6 GeV/c, the suppression of the R PbPb for electrons from beauty-hadron decays is about 1.2σ less. This difference is consistent with the ordering of charm and beauty suppression seen in the prompt D meson and J/ψ from B meson comparison [34,40,41].Within uncertainties, the R pPb is described by pQCD calculations including modifications of the parton distribution functions (FONLL [29-31] + EPS09NLO [90] nuclear PDFs) as shown in figure 7 (left). The data and the calculation suggest that cold nuclear matter effects are small at high transverse momentum.…”

supporting

confidence: 77%

“…the parton p T spectrum and the fragmentation into hadrons [13,39]. Furthermore, the nuclear modification factors R PbPb of prompt D mesons and of J/ψ from B meson decays were compared in the p T interval 8 < p T < 16 GeV/c for D mesons and 6.5 < p T < 30 GeV/c for J/ψ mesons in order to have a similar average p T (≈10 GeV/c) for the heavy hadrons [34,40,41]. This comparison with models indicates that charm quarks lose more energy than beauty quarks in this p T interval in central Pb-Pb collisions.…”

Section: Jhep07(2017)052mentioning

confidence: 99%

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Measurement of electrons from beauty-hadron decays in p-Pb collisions at s N N = 5.02 $$ \sqrt{s_{\mathrm{NN}}}=5.02 $$ TeV and Pb-Pb collisions at s N N = 2.76 $$ \sqrt{s_{\mathrm{NN}}}=2.76 $$ TeV

Adam¹,

Milošević²,

Bíró³

et al. 2017

J. High Energ. Phys.

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The production of beauty hadrons was measured via semi-leptonic decays at mid-rapidity with the ALICE detector at the LHC in the transverse momentum interval 1 < p T < 8 GeV/c in minimum-bias p-Pb collisions at √ s NN = 5.02 TeV and in 1.3 < p T < 8 GeV/c in the 20% most central Pb-Pb collisions at √ s NN = 2.76 TeV. The pp reference spectra at √ s = 5.02 TeV and √ s = 2.76 TeV, needed for the calculation of the nuclear modification factors R pPb and R PbPb , were obtained by a pQCD-driven scaling of the cross section of electrons from beauty-hadron decays measured at √ s = 7 TeV. In the p T interval 3 < p T < 8 GeV/c, a suppression of the yield of electrons from beauty-hadron decays is observed in Pb-Pb compared to pp collisions. Towards lower p T , the R PbPb values increase with large systematic uncertainties. The R pPb is consistent with unity within systematic uncertainties and is well described by theoretical calculations that include cold nuclear matter effects in p-Pb collisions. The measured R pPb and these calculations indicate that cold nuclear matter effects are small at high transverse momentum also in Pb-Pb collisions. Therefore, the observed reduction of R PbPb below unity at high p T may be ascribed to an effect of the hot and dense medium formed in Pb-Pb collisions. Keywords: Heavy Ion ExperimentsArXiv ePrint: 1609.03898Open Access, Copyright CERN, for the benefit of the ALICE Collaboration. Article funded by SCOAP 3 .https://doi.org/10.1007/JHEP07(2017)052 The ALICE collaboration 33 JHEP07(2017)052 IntroductionIn collisions of heavy nuclei at ultra-relativistic energies, a high-density colour-deconfined state of strongly-interacting matter, called Quark-Gluon Plasma (QGP), is expected to be produced [1,2]. Due to their large masses (m Q Λ QCD ), heavy quarks (charm and beauty) are almost exclusively produced in the early stage of the collision via hard parton scatterings characterised by production-time scales of less than 0.1 and 0.01 fm/c for charm and beauty quarks, respectively [3]. They can, therefore, serve as probes to test the mechanisms of medium-induced parton energy loss, because the formation time of the QGP medium is expected to be about 0.3 fm/c [4] and its decoupling time is about 10 fm/c for collisions at LHC energies [5]. Due to their stronger colour coupling to the medium gluons are argued to lose more energy than quarks [6][7][8]. Furthermore, the radiative energy loss of heavy quarks is predicted to be reduced with respect to light quarks due to the massdependent restriction of the phase space into which medium-induced gluon radiation can take place (dead-cone effect) [9][10][11][12]. The effect of the charm-quark mass on energy loss becomes negligible at high transverse momentum, p T 10 GeV/c, where the ratio m c /p T approaches zero [13]. Therefore, due to the larger mass, beauty quarks can be sensitive -1 - JHEP07(2017)052probes for testing the mass dependence of the parton energy loss up to transverse momenta well above 10 GeV/c [13]. Final-state effects, such ...

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supporting

confidence: 77%

Section: Jhep07(2017)052mentioning

confidence: 99%

Measurement of electrons from beauty-hadron decays in p-Pb collisions at s N N = 5.02 $$ \sqrt{s_{\mathrm{NN}}}=5.02 $$ TeV and Pb-Pb collisions at s N N = 2.76 $$ \sqrt{s_{\mathrm{NN}}}=2.76 $$ TeV

Adam¹,

Milošević²,

Bíró³

et al. 2017

J. High Energ. Phys.

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“…In the charmonium sector, ALICE presented a clear sign of a low transverse momentum (p T ) J/ψ production component leading to a larger nuclear modification factor R AA [7,8,9,10,12], i.e., a weaker suppression compared to the results at RHIC by PHENIX [13] and STAR [14,15] for the p T integrated results and at low p T . This increase has been widely interpreted as a signature of late-stage J/ψ production either during the life-time of the deconfined medium produced in heavy-ion collisions proposed in Ref.…”

Section: Run 1 Results and First Run Glimpsesmentioning

confidence: 98%

Prospects for Quarkonium Measurements in p–A and A–A Collisions at the LHC

Winn

2017

Few-Body Syst

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“…The fraction of non-prompt to inclusive J/ψ yields, f b , is shown in Fig. 3 as a function of N part for 1.5 < p T < 10 GeV/c (left) and as a function of p T for 0 − 50 % collision centralities (right) [12]. No significant dependence on centrality is observed.…”

mentioning

confidence: 99%

“…Ratio of non-prompt to inclusive J/ψ yields measured at mid-rapidity (|y| < 0.8), as a function of N part (left) and p T (right). Results are compared to similar measurements by CMS in Pb − Pb collisions as well as by ALICE, ATLAS, CMS and CDF in pp collisions [12].…”

mentioning

confidence: 99%

Charmonium production in Pb–Pb collisions with ALICE at the LHC

Costa

2016

Nuclear Physics A

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We report on published charmonium measurements performed by ALICE, at the LHC, in Pb − Pb collisions at a center of mass energy per nucleon-nucleon collision √ s NN = 2.76 TeV, at both mid (|y| < 0.8) and forward (2.5 < y < 4) rapidities. The nuclear modification factor of inclusive J/ψ is presented as a function of the collision centrality and the J/ψ transverse momentum, p T . The variation of the J/ψ mean transverse momentum square as a function of the collision centrality is also discussed. These measurements are compared to state of the art models that include one or several of the following mechanisms: color screening of the charm quarks, statistical hadronization at the QGP phase boundary, balance between J/ψ dissociation and regeneration in the QGP, J/ψ interaction with a dense comoving medium. Results on the production of the heavier and less bound ψ(2S) meson in Pb − Pb collisions at forward-rapidity are also presented and compared to both models and measurements performed by other experiments. At mid-rapidity we also report on ALICE unique capability to separate prompt and non-prompt J/ψ production down to low p T (≥ 1.5 GeV/c) and thus disentangle between effects on prompt J/ψ mesons and energy loss of b quarks in the QGP.Keywords: Heavy-ion, ALICE, Quark-Gluon Plasma, Charmonium, J/ψ Charmonia (for instance J/ψ and ψ(2S)) are mesons formed of a charm and anti-charm quark pair. In relativistic Heavy-Ion (HI) collisions, such as those delivered by the LHC in 2010 and 2011, their production is expected to be altered by the formation of a Quark-Gluon Plasma (QGP), a state of the nuclear matter predicted by Lattice QCD calculations at high temperature and energy density and for which quarks and gluons are deconfined. Such modifications are quantified using the nuclear modification factor R AA , which is the ratio between the charmonium yield measured in HI collisions and the cross section measured in pp at the same energy, further normalized by the nuclear overlap function T AB . A suppression of the charmonium production in HI collisions with respect to pp corresponds to R AA < 1 whereas an enhancement corresponds to R AA > 1.The left panel of Fig. 1 shows the J/ψ R AA measured by ALICE at forward rapidity (2.5 < y < 4) in Pb − Pb collisions at √ s NN = 2.76 TeV as a function of the number of nucleons participating to the collisionIt is compared to a measurement by PHENIX in Au − Au collisions at. In both cases a suppression is observed for central collisions (large values of N part ), attributed for the most part to the formation of the QGP. It is however less pronounced for ALICE than PHENIX, although the collision energy is more than 10 times larger. This property has been attributed to the onset of a recombination component to the J/ψ production at LHC energies, which counterbalances the suppression observed already at lower arXiv:1512.07610v1 [nucl-ex]

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Inclusive, prompt and non-prompt J/ψ production at mid-rapidity in Pb-Pb collisions at s N N = 2.76 $$ \sqrt{s_{\mathrm{NN}}}=2.76 $$ TeV

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