The concealment of accelerated information is possible

TL;DR

This paper explores how accelerated two-qubit systems can be effectively masked using minimal qubits, maintaining information security against decoherence and enabling acceleration parameter estimation.

Contribution

It demonstrates that information can be masked in entangled or separable states, with robustness against decoherence, and analyzes the fidelity of the masking process under acceleration.

Findings

Information can be masked in entangled or separable states.

Fidelity remains above 96% even at high acceleration.

Masking effectiveness increases with initial entanglement.

Abstract

The possibility of masking an accelerated two-qubit system by using a minimum number of qubits is discussed. It is shown that, the information may be masked in either entangled local states or product non-local separable states. We examine that each partition of these states satisfies the masking conditions. Due to the presence of non-local separable partition, one may consider that it is a type of quantum data hiding scheme. The local /non-local information encoded in the masked entangled state is robust against the decoherence of the acceleration process. The possibility of estimating the acceleration parameter via the entangled/separable masked state increases as the initial entanglement value increases. The efficiency of the masking process is examined by quantifying the fidelity of the accelerated state and its subsystems. It is shown that, the fidelity of the masked state is maximum at small initial acceleration, while the minimum fidelity is more than $96\%$.