Final published version
Research output: Contribution to Journal/Magazine › Journal article › peer-review
Research output: Contribution to Journal/Magazine › Journal article › peer-review
}
TY - JOUR
T1 - Prospects for quarkonium studies at the high-luminosity LHC
AU - Chapon, É.
AU - d'Enterria, D.
AU - Ducloué, B.
AU - Echevarria, M.G.
AU - Gossiaux, P.-B.
AU - Kartvelishvili, V.
AU - Kasemets, T.
AU - Lansberg, J.-P.
AU - McNulty, R.
AU - Price, D.D.
AU - Shao, H.-S.
AU - Van Hulse, C.
AU - Winn, M.
AU - Adam, J.
AU - An, L.
AU - Villar, D.Y.A.
AU - Bhattacharya, S.
AU - Celiberto, F.G.
AU - Cheshkov, C.
AU - D'Alesio, U.
AU - da Silva, C.
AU - Ferreiro, E.G.
AU - Flett, C.A.
AU - Flore, C.
AU - Garzelli, M.V.
AU - Gaunt, J.
AU - He, J.
AU - Makris, Y.
AU - Marquet, C.
AU - Massacrier, L.
AU - Mehen, T.
AU - Mezrag, C.
AU - Micheletti, L.
AU - Nagar, R.
AU - Nefedov, M.A.
AU - Ozcelik, M.A.
AU - Paul, B.
AU - Pisano, C.
AU - Qiu, J.-W.
AU - Rajesh, S.
AU - Rinaldi, M.
AU - Scarpa, F.
AU - Smith, M.
AU - Taels, P.
AU - Tee, A.
AU - Teryaev, O.
AU - Vitev, I.
AU - Watanabe, K.
AU - Yamanaka, N.
AU - Yao, X.
AU - Zhang, Y.
PY - 2022/1/31
Y1 - 2022/1/31
N2 - Prospects for quarkonium-production studies accessible during the upcoming high-luminosity phases of the CERN Large Hadron Collider operation after 2021 are reviewed. Current experimental and theoretical open issues in the field are assessed together with the potential for future studies in quarkonium-related physics. This will be possible through the exploitation of the huge data samples to be collected in proton–proton, proton–nucleus and nucleus–nucleus collisions, both in the collider and fixed-target modes. Such investigations include, among others, those of: (i) J/ψ and Υ produced in association with other hard particles; (ii) χc,b and ηc,b down to small transverse momenta; (iii) the constraints brought in by quarkonia on gluon PDFs, nuclear PDFs, TMDs, GPDs and GTMDs, as well as on the low-x parton dynamics; (iv) the gluon Sivers effect in polarised-nucleon collisions; (v) the properties of the quark–gluon plasma produced in ultra-relativistic heavy-ion collisions and of collective partonic effects in general; and (vi) double and triple parton scatterings.
AB - Prospects for quarkonium-production studies accessible during the upcoming high-luminosity phases of the CERN Large Hadron Collider operation after 2021 are reviewed. Current experimental and theoretical open issues in the field are assessed together with the potential for future studies in quarkonium-related physics. This will be possible through the exploitation of the huge data samples to be collected in proton–proton, proton–nucleus and nucleus–nucleus collisions, both in the collider and fixed-target modes. Such investigations include, among others, those of: (i) J/ψ and Υ produced in association with other hard particles; (ii) χc,b and ηc,b down to small transverse momenta; (iii) the constraints brought in by quarkonia on gluon PDFs, nuclear PDFs, TMDs, GPDs and GTMDs, as well as on the low-x parton dynamics; (iv) the gluon Sivers effect in polarised-nucleon collisions; (v) the properties of the quark–gluon plasma produced in ultra-relativistic heavy-ion collisions and of collective partonic effects in general; and (vi) double and triple parton scatterings.
KW - High Luminosity
KW - Large Hadron Collider (LHC)
KW - Quarkonium production
KW - Colliding beam accelerators
KW - Hadrons
KW - Heavy ions
KW - 'current
KW - Data sample
KW - Fixed targets
KW - High luminosity
KW - Large Hadron Collider
KW - Large-hadron colliders
KW - Nucleus-nucleus collision
KW - Quarkonia
KW - Luminance
U2 - 10.1016/j.ppnp.2021.103906
DO - 10.1016/j.ppnp.2021.103906
M3 - Journal article
VL - 122
JO - Progress in Particle and Nuclear Physics
JF - Progress in Particle and Nuclear Physics
M1 - 103906
ER -