Quantum algorithms for transport coefficients in gauge theories

TL;DR

This paper proposes a quantum algorithm to compute transport coefficients in gauge theories, which are crucial for modeling heavy ion collisions, potentially enabling more accurate simulations with future quantum computers.

Contribution

The paper introduces a novel quantum algorithm for calculating transport coefficients in gauge theories, including methods to construct lattice operators and prepare thermal states.

Findings

Algorithm reduces the need for large-scale collision simulations.

Provides a framework for quantum computation of gauge theory observables.

Lays groundwork for future quantum simulations of heavy ion physics.

Abstract

In the future, ab initio quantum simulations of heavy ion collisions may become possible with large-scale fault-tolerant quantum computers. We propose a quantum algorithm for studying these collisions by looking at a class of observables requiring dramatically smaller volumes: transport coefficients. These form nonperturbative inputs into theoretical models of heavy ions; thus, their calculation reduces theoretical uncertainties without the need for a full-scale simulation of the collision. We derive the necessary lattice operators in the Hamiltonian formulation and describe how to obtain them on quantum computers. Additionally, we discuss ways to efficiently prepare the relevant thermal state of a gauge theory.