Information locking and its resource efficient extraction

TL;DR

This paper investigates resource-efficient quantum information locking protocols among multiple parties, demonstrating how to minimize entanglement consumption for complete information retrieval while maintaining security.

Contribution

It introduces a class of locally indistinguishable orthogonal states that reduces entanglement use for information extraction compared to previous sets.

Findings

Locally indistinguishable states can lock information among multiple parties.

New state sets require fewer entangled states for full information retrieval.

Entanglement consumption scales linearly with the number of parties.

Abstract

Locally indistinguishable states are useful to distribute information among spatially separated parties such that the information is locked. This implies that the parties are not able to extract the information completely via local operations and classical communication (LOCC) while it might be possible via LOCC when the parties share entanglement. In this work, we consider an information distribution protocol using orthogonal states for m >= 3 spatially separated parties such that even if any k <= (m-1) parties collaborate still the information cannot be revealed completely. Such a protocol is useful to understand up to what extent the encoded information remains locked. However, if required, the parties can share entanglement and extract the information completely by LOCC. To make the process resource efficient, it should consume less number of entangled states. We show that though the set of states, which are locally indistinguishable across every bipartition, are sufficient for the above protocol, they may consume higher number of entangled states when aiming for complete information extraction. We establish this by constructing a class of locally indistinguishable sets of orthogonal states which can be employed to accomplish the above protocol and these sets consume less number of entangled states, compared to the former sets, for complete information extraction. In fact, this difference in the number of required entangled states for complete information extraction grows linearly with the number of parties. This study sheds light on suitable use of local indistinguishability property of quantum states as resource and thus, we demonstrate an efficient way of information distribution.