Abstract
The co-annihilation rate of heavy particles close to thermal equilibrium, which plays a role in many classic dark matter scenarios, can be "simulated" in QCD by considering the pair annihilation rate of a heavy quark and antiquark at a temperature of a few hundred MeV. We show that the so-called Sommerfeld factors, parameterizing the rate, can be defined and measured non-perturbatively within the NRQCD framework. Lattice measurements indicate a modest suppression in the octet channel, in reasonable agreement with perturbation theory, and a large enhancement in the singlet channel, much above the perturbative prediction. The additional enhancement is suggested to originate from bound state formation and subsequent decay. Making use of a Green's function based method to incorporate thermal corrections in perturbative co-annihilation rate computations, we show that qualitative agreement with lattice data can be found once thermally broadened bound states are accounted for. We suggest that our formalism may also be applicable to specific dark matter models which have complicated bound state structures.
Highlights
At a temperature of a few hundred MeV
We suggest that our formalism may be applicable to specific dark matter models which have complicated bound state structures
We carry out an exploratory lattice study, finding an intriguing pattern with an enhancement in the singlet channel much larger than predicted by the standard formulae used in the literature for incorporating thermal Sommerfeld enhancement
Summary
In order to outline the physics problem in a simple setting, we consider heavy quarks and antiquarks, with a pole mass M , placed in a heat bath at a temperature T ≪ M. The coefficient Γchem = 2 c neq is called the chemical equilibration rate It tells how efficiently the system is able to re-adjust its density towards the evolving neq, and encodes the effects of the microscopic processes which can change the quark and antiquark number densities, notably pair creations and annihilations. If T
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