Dissipative preparation of steady Greenberger-Horne-Zeilinger states for Rydberg atoms with quantum Zeno dynamics

TL;DR

This paper proposes a simplified method for dissipatively preparing a GHZ entangled state of three Rydberg atoms in a cavity, achieving high fidelity with fewer control fields by utilizing quantum Zeno dynamics and Rydberg pumping.

Contribution

A novel, simplified scheme for dissipative GHZ state preparation using quantum Zeno dynamics and Rydberg pumping with reduced control complexity.

Findings

Achieves approximately 98% fidelity in state preparation.

Requires only a single-mode cavity and fewer driving fields.

Numerical simulations confirm feasibility with current technology.

Abstract

Inspired by a recent work [Reiter, Reeb, and S{\o}rensen, Phys. Rev. Lett. {\bf117}, 040501 (2016)], we present a simplified proposal for dissipatively preparing a Greenberger-Horne-Zeilinger (GHZ) state of three Rydberg atoms in a cavity. The $Z$ pumping is implemented under the action of the spontaneous emission of $\Lambda$-type atoms and the quantum Zeno dynamics induced by strong continuous coupling. In the meantime, a dissipative Rydberg pumping breaks up the stability of the state $|{\rm GHZ}_+\rangle$ in the process of $Z$ pumping, making $|{\rm GHZ}_-\rangle$ be the unique steady state of system. Compared with the former scheme, the number of driving fields acting on atoms is greatly reduced and only a single-mode cavity is required. The numerical simulation of the full master equation reveals that a high fidelity $\sim98\%$ can be obtained with the currently achievable parameters in the Rydberg-atom-cavity system.