Mass corrections to the hard thermal/dense loops
Abstract
We compute corrections to the hard thermal (or dense) loop photon polarization tensor associated to a small mass m of the fermions of an electromagnetic plasma at high temperature T (or chemical potential μ). To this aim we use the on-shell effective field theory, amended with mass corrections. We also carry out the computation using transport theory, reaching to the same result. Interemediate steps in the computations reveal the presence of potential infrared divergencies. We use dimensional regularization, as it is respectful with the gauge symmetry, and then show that all infrared divergencies cancel in the final result. We compare the mass corrections with both the power and two-loop corrections, and claim that they are equally important if the mass is soft, that is, of order e T (or e μ), where e is the gauge coupling constant, but are dominat if the mass obeys e T < m T (or e μ < m μ).
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