Quantum thermodynamics and work fluctuations with applications to magnetic resonance

TL;DR

This paper introduces quantum thermodynamics and work fluctuations with applications to magnetic resonance, providing a pedagogical overview and exact calculations for single and multiple particle systems.

Contribution

It offers a clear, accessible introduction to quantum thermodynamics concepts and applies them to magnetic resonance, including exact calculations of work statistics.

Findings

Exact calculation of work statistics in magnetic resonance

Application of Jarzynski equality to quantum systems

Framework for non-equilibrium quantum thermodynamics

Abstract

In this paper we give a pedagogical introduction to the ideas of quantum thermodynamics and work fluctuations, using only basic concepts from quantum and statistical mechanics. After reviewing the concept of work, as usually taught in thermodynamics and statistical mechanics, we discuss the framework of non-equilibrium processes in quantum systems together with some modern developments, such as the Jarzynski equality and its connection to the second law of thermodynamics. We then apply these results to the problem of magnetic resonance, where all calculations may be done exactly. It is shown in detail how to build the statistics of the work, both for a single particle and for a collection of non-interacting particles. We hope that this paper may serve as a tool to bring the new student up to date on the recent developments in non-equilibrium thermodynamics of quantum systems.