Generalized Quantum Stein's Lemma and Second Law of Quantum Resource Theories

TL;DR

This paper proves a key lemma in quantum information theory, establishing a second law-like principle for quantum resources, thereby bridging thermodynamics and quantum information with new mathematical techniques.

Contribution

It develops alternative proof techniques for the generalized quantum Stein's lemma, extending the second law of quantum resource theories to static and dynamical resources.

Findings

Successfully proved the generalized quantum Stein's lemma under weaker assumptions

Reestablished the second law of quantum resource theories for states and CQ channels

Bridged the analogy between thermodynamics and quantum information theory

Abstract

The second law of thermodynamics is the cornerstone of physics, characterizing the convertibility between thermodynamic states through a single function, entropy. Given the universal applicability of thermodynamics, a fundamental question in quantum information theory is whether an analogous second law can be formulated to characterize the convertibility of resources for quantum information processing by a single function. In 2008, a promising formulation was proposed, linking resource convertibility to the optimal performance of a variant of the quantum version of hypothesis testing. Central to this formulation was the generalized quantum Stein's lemma, which aimed to characterize this optimal performance by a measure of quantum resources, the regularized relative entropy of resource. If proven valid, the generalized quantum Stein's lemma would lead to the second law for quantum resources, with the regularized relative entropy of resource taking the role of entropy in thermodynamics. However, in 2023, a logical gap was found in the original proof of this lemma, casting doubt on the possibility of such a formulation of the second law. In this work, we address this problem by developing alternative techniques to successfully prove the generalized quantum Stein's lemma under a smaller set of assumptions than the original analysis. Based on our proof, we reestablish and extend the second law of quantum resource theories, applicable to both static resources of quantum states and a fundamental class of dynamical resources represented by classical-quantum (CQ) channels. These results resolve the fundamental problem of bridging the analogy between thermodynamics and quantum information theory.