Zubarev response approach to polarization phenomena in local equilibrium

TL;DR

This paper develops a Zubarev response approach to polarization phenomena in locally equilibrated media, connecting correlation functions to established formalisms and applying it to spin physics in heavy-ion collisions.

Contribution

It introduces a novel linear response framework based on Zubarev's density operator for analyzing polarization in heavy-ion collisions, reproducing known results and exploring new aspects of spin tensor polarization.

Findings

Re-derivation of vector polarization for spin-1/2 particles.

Calculation of vector polarization for spin-1 particles showing expected contributions.

Proof that non-dissipative tensor polarization contributions vanish at leading order.

Abstract

Using the expansion of Zubarev's density operator, we develop a linear response approach to study various spin physics in a locally equilibrated medium, particularly focusing on various polarization phenomena in heavy-ion collisions. Specifically, we connect familiar correlation functions and diagrammatic methods to the Zubarev formalism, enabling the use of established techniques like the Matsubara/imaginary time formalism to facilitate calculations. For a spin-1/2 particle, we re-derive its vector polarization using this Zubarev response approach, which exactly reproduces with our previous results based on Luttinger's method. For a spin-1 particle, we calculate the vector polarization and find the expected contributions from vorticity, temperature gradients, and shear, which are identical to those for spin-1/2 particles except for a factor of 4/3 as expected. For the tensor polarization and spin alignment of a spin-1 boson, we explicitly prove that the non-dissipative contribution is zero at leading order in gradients, and briefly reiterate our previous findings for the dissipative contribution with further discussions on several concerns. Additionally, we discuss several relevant subtleties and questions, including an alternative derivation for Zubarev response approach, the covariance issues of different spin density matrix definitions, a further explanation of slow and fast modes, the mode selection scheme, etc. We also discuss skeleton expansions, higher-order contributions, and non-perturbative methods, particularly their potential connection to lattice field theory. In summary, this work discusses the foundations and subtleties of Zubarev response approach, with specific examples from spin physics in heavy-ion collisions.