Estimation of correlations and non-separability in quantum channels via unitarity benchmarking

TL;DR

This paper introduces new measures and protocols for efficiently estimating correlations and non-separability in bipartite quantum channels, advancing the analysis of quantum coherence and errors in quantum devices.

Contribution

It develops invariant sub-unitarity measures, introduces correlated unitarity as a non-separability witness, and proposes efficient randomized benchmarking protocols for their estimation.

Findings

Correlated unitarity is bounded on separable channels.

Efficient estimation of non-separability is possible with randomized benchmarking.

Protocols can reliably witness non-separability with low reset errors.

Abstract

The ability to transfer coherent quantum information between systems is a fundamental component of quantum technologies and leads to coherent correlations within the global quantum process. However correlation structures in quantum channels are less studied than those in quantum states. Motivated by recent techniques in randomized benchmarking, we develop a range of results for efficient estimation of correlations within a bipartite quantum channel. We introduce sub-unitarity measures that are invariant under local changes of basis, generalize the unitarity of a channel, and allow for the analysis of coherent information exchange within channels. Using these, we show that unitarity is monogamous, and provide a novel information-disturbance relation. We then define a notion of correlated unitarity that quantifies the correlations within a given channel. Crucially, we show that this measure is strictly bounded on the set of separable channels and therefore provides a witness of non-separability. Finally, we describe how such measures for effective noise channels can be efficiently estimated within different randomized benchmarking protocols. We find that the correlated unitarity can be estimated in a SPAM-robust manner for any separable quantum channel, and show that a benchmarking/tomography protocol with mid-circuit resets can reliably witness non-separability for sufficiently small reset errors. The tools we develop provide information beyond that obtained via simultaneous randomized benchmarking and so could find application in the analysis of cross-talk and coherent errors in quantum devices.