Proposal of ensemble qubits with two-atom decay

TL;DR

This paper introduces a new ensemble qubit implementation using two-atom decay via quantum degenerate parametric amplification, creating a stable 2D quantum manifold without needing Rydberg blockade, suitable for simple experimental setups.

Contribution

It presents a novel ensemble qubit scheme based on two-atom decay, avoiding the need for strong atom-atom interactions and Rydberg blockade, and compatible with cavity protection mechanisms.

Findings

Creates a stable 2D quantum manifold with two-atom decay

Suppresses transitions to higher-excited states

Compatible with cavity protection to reduce dephasing

Abstract

We propose and analyze a novel approach to implement ensemble qubits. The required anharmonicity is provided by a simultaneous decay of two atoms (i.e., two-atom decay), which is achieved by fully quantum degenerate parametric amplification. For an atomic ensemble, the two-atom decay generates and stabilizes a 2D quantum manifold, which is spanned by the ground and single-excited superradiant states. Moreover, this nonlinear decay process can strongly suppress transitions to higher-excited superradiant states, and convert residual transitions into an effective decay from the single-excitation superradiant state to the ground state. Our method does not require Rydberg dipole blockade and, thus, strong atom-atom interactions, compared to previous work. This indicates that it can be applied to typical atomic or spin ensembles in simple experimental setups. Remarkably, our idea is compatible with the cavity protection mechanism, and therefore spin dephasing due to inhomogeneous broadening can be strongly suppressed. The presented ensemble qubit provides a new platform for quantum information processing, and also extends the range of applications of atomic or spin ensembles.