The first law of general quantum resource theories

Creators: Sparaciari, Carlo; del Rio, Lídia; Scandolo, Carlo Maria; Faist, Philippe; Oppenheim, Jonathan

Abstract

We extend the tools of quantum resource theories to scenarios in which multiple quantities (or resources) are present, and their interplay governs the evolution of physical systems. We derive conditions for the interconversion of these resources, which generalise the first law of thermodynamics. We study reversibility conditions for multi-resource theories, and find that the relative entropy distances from the invariant sets of the theory play a fundamental role in the quantification of the resources. The first law for general multi-resource theories is a single relation which links the change in the properties of the system during a state transformation and the weighted sum of the resources exchanged. In fact, this law can be seen as relating the change in the relative entropy from different sets of states. In contrast to typical single-resource theories, the notion of free states and invariant sets of states become distinct in light of multiple constraints. Additionally, generalisations of the Helmholtz free energy, and of adiabatic and isothermal transformations, emerge. We thus have a set of laws for general quantum resource theories, which generalise the laws of thermodynamics. We first test this approach on thermodynamics with multiple conservation laws, and then apply it to the theory of local operations under energetic restrictions.

Additional Information

© 2020 This Paper is published in Quantum under the Creative Commons Attribution 4.0 International (CC BY 4.0) license. Copyright remains with the original copyright holders such as the authors or their institutions. Published: 2020-04-30. We thank the anonymous TQC referees for feedbacks, and Tobias Fritz for detailed comments on a previous version of this manuscript, CS is supported by the EPSRC (grant number EP/L015242/1). LdR acknowledges support from the Swiss National Science Foundation through SNSF project No. 200020 165843 and through the National Centre of Competence in Research Quantum Science and Technology (QSIT), and from the FQXi grant Physics of the observer. CMS is supported by the Engineering and Physical Sciences Research Council (EPSRC) through the doctoral training grant 1652538, and by Oxford-Google DeepMind graduate scholarship. CMS would like to thank the Department of Physics and Astronomy at UCL for their hospitality. PhF acknowledges support from the Swiss National Science Foundation (SNSF) through the Early PostDoc. Mobility Fellowship No. P2EZP2 165239 hosted by the Institute for Quantum Information and Matter (IQIM) at Caltech, from the IQIM which is a National Science Foundation (NSF) Physics Frontiers Center (NSF Grant PHY-1733907), from the Department of Energy Award DE-SC0018407, as well as from the Deutsche Forschungsgemeinschaft (DFG) Research Unit FOR 2724. JO is supported by the Royal Society, and by an EPSRC Established Career Fellowship. We thank the COST Network MP1209 in Quantum Thermodynamics. Author contributions: All authors contributed significantly to the ideas behind this work and to the development of the general framework (Sec. 2). CS, LdR and JO developed the results on batteries, bank states and the first law (Secs. 3, 4, 5). CS wrote the proofs and initial draft.

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