Detection of nonabsolute separability in quantum states and channels through moments

TL;DR

This paper introduces a moment-based method to efficiently detect non-absolutely separable quantum states and channels, avoiding full state tomography and demonstrating practical advantages in quantum information tasks.

Contribution

It proposes a novel, efficient detection scheme for non-absolutely separable states and channels using moments, with applications in quantum resource identification.

Findings

The method bypasses full state tomography.

Non-absolutely separable states can enhance quantum channel discrimination.

The approach effectively detects resource-preserving channels.

Abstract

In quantum information and computation, the generation of entanglement through unitary gates remains a significant and active area of research. However, there are states termed as absolutely separable, from which entanglement cannot be created through any non-local unitary action. Thus, from a resource-theoretic perspective, non-absolutely separable states are useful as they can be turned into entangled states using some appropriate unitary gates. In this work, we propose an efficient method to detect non-absolutely separable states. Our approach relies on evaluating moments that can bypass the need for full state tomography, thereby enhancing its practical applicability. We then present several examples in support of our detection scheme. We also address a closely related problem concerning states whose partial transpose remains positive under any arbitrary non-local unitary action. Furthermore, we examine the effectiveness of our moment-based approach in the detection of quantum channels that are not absolutely separating, which entails the detection of resource preserving channels. Finally, we demonstrate the operational significance of non-absolutely separable states by proving that every such state can provide an advantage in a quantum-channel discrimination task.