Improving Quantum Battery Capacity in Tripartite Quantum Systems by Local Projective Measurements

TL;DR

This paper explores how local projective measurements can enhance quantum battery capacity in tripartite systems, demonstrating improved robustness against noise and providing analytical protocols for general three-qubit X-states.

Contribution

It introduces new measurement-based protocols and optimal local projective operators to improve quantum battery capacity and noise resilience in tripartite quantum systems.

Findings

Optimal local projective operators enhance capacity against noise.

Protocols derived for general three-qubit X-states.

Numerical validation confirms capacity improvements.

Abstract

The impact of local von Neumann measurements on quantum battery capacity is investigated in tripartite quantum systems. Two measurement-based protocols are proposed and the concept of optimal local projective operators is introduced. Specifically, explicit analytical expressions are derived for the protocols when applied to general three-qubit X-states. Furthermore, the negative effects of white noise and dephasing noise on quantum battery capacity are analyzed, proving that optimal local projective operators can improve the robustness of subsystem and total system capacity against both noise types for the general tripartite X-state. The performance of different schemes in capacity enhancement are numerically validated through detailed examples and it is found that these optimized operators can effectively enhance both subsystem and total system battery capacity. The results indicate that the local von Neumann measurement is a powerful tool to enhance the battery capacity in multipartite quantum systems.