Quantum superpositions of causal orders as an operational resource

• Published in: Physical review research Vol. 1; no. 3; p. 033174
• Main Authors: Taddei, Márcio M., Nery, Ranieri V., Aolita, Leandro
• Format: Journal Article
• Language: English
• Published: American Physical Society 13.12.2019
• ISSN: 2643-1564; 2643-1564
• DOI: 10.1103/PhysRevResearch.1.033174

Causal nonseparability refers to processes where events take place in a coherent superposition of different causal orders. These may be the key resource for experimental violations of causal inequalities and have been recently identified as resources for concrete information-theoretic tasks. Here, we take a step forward by deriving a complete operational framework for causal nonseparability as a resource. Our first contribution is a formal definition for the specific notion of quantum control of causal orders, a stronger form of causal nonseparability—with the celebrated quantum switch as best-known example—where the causal orders of events for a target system are coherently controlled by a control system. We then build a resource theory—for both generic causal nonseparability as well as quantum control of causal orders—with a physically motivated class of free operations, based on process-matrix concatenations. We present the framework explicitly in the mindset with a control register. However, our machinery is totally versatile, being directly applicable also to scenarios with a target register alone. Moreover, an important subclass of our operations is free not only with respect to causal nonseparability and quantum control of causal orders but it also preserves the very causal structure of causal processes. Hence, our treatment contains, as a built-in feature, the basis of a resource theory of quantum causal networks too. As applications, first, we establish a simple sufficient condition for pure-process free convertibility. This imposes a hierarchy of quantum control of causal orders with the quantum switch at the top. Second, we prove that causal-nonseparability distillation exists. More precisely, we show how to convert multiple copies of a process with arbitrarily little causal nonseparability into fewer copies of a quantum switch. Our findings reveal conceptually new, unexpected phenomena, with both fundamental and practical implications.