Fast generation of N-atom Greenberger-Horne-Zeilinger state in separate coupled cavities via transitionless quantum driving

TL;DR

This paper presents a fast, efficient method using transitionless quantum driving to generate multi-atom GHZ states in separate cavities connected by optical fibers, outperforming traditional adiabatic techniques.

Contribution

It introduces a novel TQD-based scheme for rapid GHZ state generation in distributed cavity systems, with robustness against decoherence and scalability to N atoms.

Findings

The TQD scheme is faster than traditional adiabatic methods.

The method is insensitive to atomic spontaneous emission and fiber photon leakage.

Numerical simulations confirm the scheme's robustness and scalability.

Abstract

By jointly using quantum Zeno dynamics and the approach of "transitionless quantum driving (TQD)" proposed by Berry to construct shortcuts to adiabatic passage (STAP), we propose an efficient scheme to fast generate multiatom Greenberger-Horne-Zeilinger (GHZ) states in separate cavities connected by opitical fibers only by one-step manipulation. We first detail the generation of the three-atom GHZ states via TQD, then, we compare the proposed TQD scheme with the traditional ones with adiabatic passage. At last, the influence of various decoherence factors, such as spontaneous emission, cavity decay and fiber photon leakage, is discussed by numerical simulations. All the results show that the present TQD scheme is fast and insensitive to atomic spontaneous emission and fiber photon leakage. Furthermore, the scheme can be directly generalized to realize N-atom GHZ states generation by the same principle in theory.