Kubo formula for spin hydrodynamics: spin chemical potential as leading order in gradient expansion

Abstract

We present a first-order dissipative spin hydrodynamic framework, where the spin chemical potential ωμ is treated as the leading term in the hydrodynamic gradient expansion, i.e., ωμ O(1). We argue that for the consistency of the theoretical framework, the energy-momentum tensor needs to be symmetric at least up to order O(∂). We consider the phenomenological form of the spin tensor, where it is anti-symmetric in the last two indices only. A comprehensive analysis of spin hydrodynamics is conducted using both macroscopic entropy current analysis and microscopic Kubo formalism, establishing consistency between the two approaches. A key finding is the entropy production resulting from spin-orbit coupling, which alters the traditional equivalence between the Landau and Eckart fluid frames. Additionally, we identify cross-diffusion effects, where vector dissipative currents are influenced by gradients of both spin chemical potential and chemical potential corresponding to the conserved charge through off-diagonal transport coefficients. Two distinct methods for decomposing the spin tensor are proposed, and their equivalence is demonstrated through Kubo relations.

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