Landau Damping in a strong magnetic field: Dissociation of Quarkonia

TL;DR

This paper studies how strong magnetic fields influence quarkonia properties and their dissociation in a thermal medium, revealing increased dissociation temperatures and differential effects on various quarkonium states.

Contribution

It provides a detailed analysis of magnetic field effects on quarkonia, including modifications to potential, size, binding energies, and dissociation temperatures, using resummed propagators in a thermal medium.

Findings

Magnetic field makes the real part of the potential more attractive.

Dissociation temperatures of quarkonia increase with magnetic field strength.

Magnetic field causes differential effects on different quarkonium states.

Abstract

We have investigated the effects of strong magnetic field on the properties of quarkonia immersed in a thermal medium of quarks and gluons and studied its quasi-free dissociation due to the Landau-damping. Thermalizing the Schwinger propagator in the lowest Landau levels for quarks and the Feynman propagator for gluons in real-time formalism, we have calculated the resummed retarded and symmetric propagators, which in turn give the real and imaginary components of dielectric permittivity, respectively. The magnetic field affects the large-distance interaction more than the short-distance interaction, as a result, the real part of potential becomes more attractive and the magnitude of imaginary part too becomes larger, compared to the thermal medium in absence of strong magnetic field. As a consequence the average size of $J/\psi$'s and $\psi^\prime$'s are increased but $\chi_c$'s get shrunk. Similarly the magnetic field affects the binding of $J/\psi$'s and $\chi_c$'s discriminately, i.e. it decreases the binding of $J/\psi$ and increases for $\chi_c$. However, the further increase in magnetic field results in the decrease of binding energies. On contrary the magnetic field increases the width of the resonances, unless the temperature is sufficiently high. We have finally studied how the presence of magnetic field affects the dissolution of quarkonia in a thermal medium due to the Landau damping, where the dissociation temperatures are found to increase compared to the thermal medium in absence of magnetic field. However, further increase of magnetic field decreases the dissociation temperatures. For example, $J/\psi$'s and $\chi_c$'s are dissociated at higher temperatures at 2 $T_c$ and 1.1 $T_c$ at a magnetic field $eB \approx 6~{\rm{and}}~4~m_\pi^2$, respectively, compared to the values 1.60 $T_c$ and 0.8 $T_c$ in the absence of magnetic field, respectively.