Bottomonium suppression in an open quantum system using the quantum trajectories method

Brambilla, Nora; Escobedo, Miguel Ángel; Strickland, Michael; Vairo, Antonio; Griend, Peter Vander; Weber, Johannes Heinrich

doi:10.1007/jhep05(2021)136

Cited by 81 publications

(72 citation statements)

References 95 publications

(204 reference statements)

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“…In this work, we consider mediuminduced bound state formation and dissociation in non-Abelian gauge theories. In order to compute these processes precisely in a proper thermal field theoretical approach, we apply the open quantum system framework, which has been intensively used to investigate quarkonium transport [56][57][58][59][60][61][62][63][64][65][66][67][68][69][70] and jet quenching [71][72][73] in the QGP. In particular, we consider a subsystem consisting of a pair of heavy particles, interacting weakly with a thermal environment, i.e., the hot plasma.…”

Section: Introductionmentioning

confidence: 99%

Non-Abelian electric field correlator at NLO for dark matter relic abundance and quarkonium transport

Binder

Mukaida

Scheihing-Hitschfeld

et al. 2022

J. High Energ. Phys.

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We perform a complete next-to-leading order calculation of the non-Abelian electric field correlator in a SU(Nc) plasma, which encodes properties of the plasma relevant for heavy particle bound state formation and dissociation, and is different from the correlator for the heavy quark diffusion coefficient. The calculation is carried out in the real-time formalism of thermal field theory and includes both vacuum and finite temperature contributions. By working in the Rξ gauge, we explicitly show the results are gauge independent, infrared and collinear safe. The renormalization group equation of this electric field correlator is determined by that of the strong coupling constant. Our next-to-leading order calculation can be directly applied to any dipole singlet-adjoint transition of heavy particle pairs. For example, it can be used to describe dissociation and (re)generation of heavy quarkonia inside the quark-gluon plasma well below the melting temperature, as well as heavy dark matter pairs (or charged co-annihilating partners) in the early universe.

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Section: Introductionmentioning

confidence: 99%

Non-Abelian electric field correlator at NLO for dark matter relic abundance and quarkonium transport

Binder

Mukaida

Scheihing-Hitschfeld

et al. 2022

J. High Energ. Phys.

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“…Fundamentally, the computation of the survival probability of a given bottomonium state can be cast into the framework of open quantum systems (OQS) in which there is JHEP10(2021)083 a probe (bottomonium states) and medium (light quarks and gluons). Within the OQS framework, in order to describe the in-medium evolution of bottomonium states one must trace over the medium degrees of freedom and obtain evolution equations for the reduced density matrix of the system [6][7][8][9][10][11][12][13][14][15][16][17][18][19]. In the limit that the medium relaxation time scale and the intrinsic time scale of the probe are much smaller than the probe relaxation time scale, the resulting dynamical equation for the reduced density matrix can be cast into a so-called Lindblad form [20,21].…”

Section: Introductionmentioning

confidence: 99%

The imaginary part of the heavy-quark potential from real-time Yang-Mills dynamics

Boguslavski

Kasmaei

Strickland

2021

J. High Energ. Phys.

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We extract the imaginary part of the heavy-quark potential using classical-statistical simulations of real-time Yang-Mills dynamics in classical thermal equilibrium. The r-dependence of the imaginary part of the potential is extracted by measuring the temporal decay of Wilson loops of spatial length r. We compare our results to continuum expressions obtained using hard thermal loop theory and to semi-analytic lattice perturbation theory calculations using the hard classical loop formalism. We find that, when plotted as a function of mDr, where mD is the hard classical loop Debye mass, the imaginary part of the heavy-quark potential shows little sensitivity to the lattice spacing at small mDr ≲ 1 and agrees well with the semi-analytic hard classical loop result. For large quark-antiquark separations, we quantify the magnitude of the non-perturbative long-range corrections to the imaginary part of the heavy-quark potential. We present our results for a wide range of temperatures, lattice spacings, and lattice volumes. This work sets the stage for extracting the imaginary part of the heavy-quark potential in an expanding non-equilibrium Yang Mills plasma.

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“…We expand to linear order in / the master equation derived in [12] which at order 0 in / takes the form of a Lindblad equation which was solved in Refs. [12][13][14][15]. We follow the procedure of Blaizot and Escobedo of Ref.…”

Section: Discussionmentioning

confidence: 99%

“…[11,12], is the dispersive counterpart of . In this limit, the master equation can be written in Lindblad form; previous works solved this Lindblad equation and extracted experimental observables including the nuclear modification factor and the elliptic flow 2 [13][14][15].…”

Section: Pos(charm2020)039mentioning

confidence: 99%

In medium Langevin dynamics of heavy quarkonium

Griend¹

2021

Proceedings of 10th International Workshop on Charm Physics — PoS(CHARM2020)

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Heavy quarks and their bound states are ideal probes of the quark gluon plasma formed in relativistic heavy ion collisions. Due to the hierarchy of scales of the system, the in-medium dynamics of heavy quarkonium can be modeled by a Langevin equation in which uncorrelated interactions with the medium alter the momentum of the bound state. The hierarchy of scales makes the problem ideally suited for the use of effective field theories, namely potential nonrelativistic QCD, and the formalism of open quantum systems. We utilize these tools to perform a first principles treatment of heavy quarkonium in medium and analyze the regimes in which the dynamics take the form of a Langevin equation.

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Bottomonium suppression in an open quantum system using the quantum trajectories method

Cited by 81 publications

References 95 publications

Non-Abelian electric field correlator at NLO for dark matter relic abundance and quarkonium transport

Non-Abelian electric field correlator at NLO for dark matter relic abundance and quarkonium transport

The imaginary part of the heavy-quark potential from real-time Yang-Mills dynamics

In medium Langevin dynamics of heavy quarkonium

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