# Quantum thermodynamics in a multipartite setting: A resource theory of   local Gaussian work extraction for multimode bosonic systems

**Authors:** Uttam Singh, Michael G. Jabbour, Zacharie Van Herstraeten, Nicolas J., Cerf

arXiv: 1905.02948 · 2019-10-09

## TL;DR

This paper develops a resource theory framework for local Gaussian work extraction in multimode bosonic systems, identifying free states and operations, and establishing conditions under which local work extraction is possible.

## Contribution

It introduces a novel resource theory for local Gaussian work extraction in multipartite bosonic systems, defining free states, operations, and a monotone for quantifying local activity.

## Key findings

- Local Gaussian extractable work is zero for free states.
- The resource monotone is based on covariance matrix traces.
- Examples demonstrate distillation of local activity and work.

## Abstract

Quantum thermodynamics can be cast as a resource theory by considering free access to a heat bath, thereby viewing the Gibbs state at a fixed temperature as a free state and hence any other state as a resource. Here, we consider a multipartite scenario where several parties attempt at extracting work locally, each having access to a local heat bath (possibly with a different temperature), assisted with an energy-preserving global unitary. As a specific model, we analyze a collection of harmonic oscillators or a multimode bosonic system. Focusing on the Gaussian paradigm, we construct a reasonable resource theory of local activity for a multimode bosonic system, where we identify as free any state that is obtained from a product of thermal states (possibly at different temperatures) acted upon by any linear-optics (passive Gaussian) transformation. The associated free operations are then all linear-optics transformations supplemented with tensoring and partial tracing. We show that the local Gaussian extractable work (if each party applies a Gaussian unitary, assisted with linear optics) is zero if and only if the covariance matrix of the system is that of a free state. Further, we develop a resource theory of local Gaussian extractable work, defined as the difference between the trace and symplectic trace of the covariance matrix of the system. We prove that it is a resource monotone that cannot increase under free operations. We also provide examples illustrating the distillation of local activity and local Gaussian extractable work.

## Full text

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## Figures

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## References

69 references — full list in the complete paper: https://tomesphere.com/paper/1905.02948/full.md

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Source: https://tomesphere.com/paper/1905.02948