The content discusses the development of a general framework for quantum resource theories (QRTs) with a second law, similar to the second law of thermodynamics. The key to this framework is the generalized quantum Stein's lemma, which aims to characterize the optimal performance of a variant of quantum hypothesis testing.
The main points are:
Quantum information processing relies on the efficient use of intrinsic quantum properties, such as entanglement and coherence, which serve as resources. QRTs provide an operational framework for studying the manipulation and quantification of these quantum resources.
The construction of QRTs is analogous to the axiomatic formulation of thermodynamics, which reveals the potential uses and fundamental limits of energy resources. Similarly, QRTs aim to quantify the potential and limit of quantum resources.
A fundamental task in QRTs is the asymptotic conversion between quantum states, which involves converting many independent and identically distributed (IID) copies of one state into as many copies of another state as possible with a vanishing error under restricted operations.
The generalized quantum Stein's lemma characterizes the optimal performance of a variant of quantum hypothesis testing, which is central to establishing a second law for QRTs, analogous to the second law of thermodynamics.
The authors prove the generalized quantum Stein's lemma by developing alternative techniques to handle the non-IIDness of the alternative hypothesis, which was a key challenge in previous attempts.
Based on the proof of the generalized quantum Stein's lemma, the authors reestablish and extend the formulation of QRTs with the second law, applicable to both static and dynamical resources.
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arxiv.org
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