Abstract
Our first aim is to explore the effect of the collision integral with the insurance of instantaneous conservation of particle number on charge and heat transport in a thermal QCD medium. The second aim is to see how the dimensional reduction due to strong magnetic field (B) modulates the transport through the entangled effects, {\em such as} collision-time and occupation probability etc. in collision integral. The final aim is to check how the quasiparticle description through dispersion relation of thermal QCD in strong B, alters the aforesaid conclusions. We observe that modified collision term expedites both transport, which is manifested by large magnitudes of electrical ($\sigma_{\rm el}$) and thermal ($\kappa$) conductivities, in comparison to relaxation-collision term. As a corollary, Lorenz number is dominated by the later and Knudsen number is by the former. However, strong B not only flips the dominance of collision term in heat transport, it also causes drastic enhancement of both $\sigma_{\rm el}$ and $\kappa$ and reduction in specific heat. As a result, the equilibration factor, Knudsen number becomes much larger than one, which defies physical interpretation. Finally, quasiparticle description in the absence of strong B impedes the transport of charge and heat, resulting in the meagre decrease of conductivities, however, strong B does noticeable observations: conductivities now gets reduced to physically plausible values, T-dependence of $\sigma_{\rm el}$ gets reversed, {\em i.e.} it now decreases with T, effect of collision integral gets smeared in $\kappa$ etc. Knudsen number thus becomes much smaller than one, implying that the system be remained in equilibrium. These findings attribute to the fact that the collective modes in the dispersion relation of thermal QCD in strong B sets in much larger scale, manifested by large in-medium masses.
Highlights
Quark gluon plasma (QGP), a deconfined state of quarks and gluons is formed in heavy ion collision experiments at Relativistic Heavy Ion Collider (RHIC) and Large Hadron Collider (LHC)
We have found that the modified collision integral enhances the magnitudes of both conductivities, especially more to the electrical conductivity, compared to the counterparts with the collision term of relaxation type
II, we have investigated the effect of the collision term via the collision integral and the effect of magnetic field on the charge and heat transport, separately, in a thermal medium of noninteracting quarks and gluons
Summary
Quark gluon plasma (QGP), a deconfined state of quarks and gluons is formed in heavy ion collision experiments at Relativistic Heavy Ion Collider (RHIC) and Large Hadron Collider (LHC). The Knudsen number does not depend on the type of collision integral and becomes much smaller than one, which ensures that the system is still in local equilibrium even in the presence of strong B This could be envisaged by the fact that the collective oscillation of a thermal QCD medium in strong B sets in much bigger scale than in the absence of magnetic field. We have found that the magnitude of conductivities for noninteracting partons in strong magnetic field defy physical interpretation, contrary to the spirit of the linearization of the collision integral on the basis of near-equilibrium assumption
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