Thermalization in weakly coupled nonabelian plasmas

We complete the physical picture for the evolution of a high-energy jet propagating through a weakly-coupled quark-gluon plasma by investigating the thermalization of the soft components of the jet. We argue that the following scenario should hold: the leading particle emits a significant number of mini-jets which promptly evolve via quasidemocratic branchings and thus degrade into a myriad of soft gluons, with energies of the order of the medium temperature T . Via elastic collisions with the medium constituents, these soft gluons relax to local thermal equilibrium with the plasma over a time scale which is considerably shorter than the typical lifetime of the mini-jet. The thermalized gluons form a tail which lags behind the hard components of the jet. We support this scenario, first, via parametric arguments and, next, by studying a simplified kinetic equation, which describes the jet dynamics in longitudinal phase-space. We solve the kinetic equation using both (semi-)analytical and numerical methods. In particular, we obtain the first exact, analytic, solutions to the ultrarelativistic Fokker-Planck equation in one-dimensional phase-space. Our results confirm the physical picture aforementioned and demonstrate the quenching of the jet via multiple branching followed by the thermalization of the soft gluons in the cascades.

“…(3.6) admits the turbulent spectrum f ∝ 1/p 7/2 as a fixed point [28,36,41]. On the other hand, it does not vanish when f approaches the thermal distribution f eq (p) ∝ e −p/T .…”

Section: Jhep10(2015)155mentioning

confidence: 99%

Section: Jhep10(2015)155mentioning

confidence: 99%

See 1 more Smart Citation

Thermalization of mini-jets in a quark-gluon plasma

Iancu

2015

“…This part of the evolution is characterized by negative values of the longitudinal pressure P L , which is a result of the coherence of the approximately boost invariant fields. However, classical numerical simulations [21,29] (as well as analytical series solutions to the classical equations of motion [30,31]) show that in a timescale Q s τ ∼ 1, the coherence is lost, the longitudinal pressure approaches zero P L ∼ 0, and the occupancies become perturbative [32][33][34][35]. At this point the system may be passed to the EKT [16,[36][37][38].…”

Section: Hydrodynamization Of Fluctuations Far From Equilibriummentioning

confidence: 99%

Initial conditions for hydrodynamics from weakly coupled pre-equilibrium evolution

Keegan

Kurkela

Mazeliauskas

et al. 2016

Self Cite

117

We use effective kinetic theory, accurate at weak coupling, to simulate the preequilibrium evolution of transverse energy and flow perturbations in heavy-ion collisions. We provide a Green function which propagates the initial perturbations to the energymomentum tensor at a time when hydrodynamics becomes applicable. With this map, the complete pre-thermal evolution from saturated nuclei to hydrodynamics can be modelled in a perturbatively controlled way.

“…Even in perturbative reheating scenarios, the dynamics can be modified significantly by thermal and plasma effects [77,[79][80][81][82][83][84][85][86][87][88][89][90][91][92][93][94]. Thermal masses produced as a sector heats up could modify or block energy transport [81], and energy transfer by scattering can be important, as can the quasiparticle and collective excitation dynamics [77].…”

Section: Jhep09(2017)113mentioning

confidence: 99%

Symmetric and asymmetric reheating

Hardy¹,

Unwin²

2017

We study models in which the inflaton is coupled to two otherwise decoupled sectors, and the effect of preheating and related processes on their energy densities during the evolution of the universe. Over most of parameter space, preheating is not disrupted by the presence of extra sectors, and even comparatively weakly coupled sectors can get an order 1 fraction of the total energy at this time. If two sectors are both preheated, the high number densities could also lead to inflaton mediated thermalisation. If only one sector is preheated, Bose enhancement of the late time inflaton decays may cause significant deviations from the perturbative prediction for their relative reheat temperatures. Meanwhile, in Non-Oscillatory inflation models resonant effects can result in exponentially large final temperature differences between sectors that have similar couplings to the inflaton. Asymmetric reheating is potentially relevant for a range of beyond the Standard Model physics scenarios. We show that in dark matter freeze-in models, hidden sector temperatures a factor of 10 below that of the visible sector are typically needed for the relic abundance to be set solely by freeze-in dynamics.