Thermodynamic analysis of quantum error correcting engines

TL;DR

This paper explores the thermodynamic properties of quantum error correcting codes by modeling them as quantum heat engines, analyzing entropy production, irreversibility, and work costs for classical and quantum codes.

Contribution

It provides a detailed thermodynamic assessment of quantum error correction cycles, including entropy and work costs, highlighting irreversibility sources and effects of quantum coherence.

Findings

Work cost of correction gates linked to error-induced heat

Encoding/decoding costs are always positive due to irreversibility

Correcting quantum coherences involves significant modifications with Hadamard gates

Abstract

Quantum error correcting codes can be cast in a way which is strikingly similar to a quantum heat engine undergoing an Otto cycle. In this paper we strengthen this connection further by carrying out a complete assessment of the thermodynamic properties of 4-strokes operator-based error correcting codes. This includes an expression for the entropy production in the cycle which, as we show, contains clear contributions stemming from the different sources of irreversibility. To illustrate our results, we study a classical 3-qubit error correcting code, well suited for incoherent states, and the 9-qubit Shor code capable of handling fully quantum states. We show that the work cost associated with the correction gate is directly associated with the heat introduced by the error. Moreover, the work cost associated with encoding/decoding quantum information is always positive, a fact which is related to the intrinsic irreversibility introduced by the noise. Finally, we find that correcting the coherent (and thus genuinely quantum) part of a quantum state introduces substantial modifications related to the Hadamard gates required to encode and decode coherences.