Dissipative quantum repeater

TL;DR

This paper proposes a dissipative quantum repeater protocol for entangling distant atoms, incorporating realistic dissipation effects, and demonstrates methods to transfer entanglement effectively despite these losses.

Contribution

It introduces a practical quantum repeater scheme accounting for dissipation, using Bell state measurement and cavity QED to transfer entanglement between distant atoms.

Findings

Entanglement can be successfully transferred despite dissipation.

Dissipation effects can be minimized by optimal cavity and atom choices.

Concurrence and success probability can be maximized with low detuning.

Abstract

By implementing a quantum repeater protocol, our aim in this paper is the production of entanglement between two two-level atoms locating far from each other. To make our model close to experimental realizations, the atomic and field sources of dissipations are also taken into account. We consider eight of such atoms (1, 2, ..., 8) sequentially located in a line which begins (ends) with atom 1 (8). We suppose that, initially the four atomic pairs (i; i + 1), i = 1; 3; 5; 7 are mutually prepared in maximally entangled states. Clearly, the atoms 1; 8, the furthest atoms which we want to entangle them are never entangled, initially. To achieve the purpose of paper, at first we perform the interaction between the atoms (2; 3) as well as (6; 7) which results in the entanglement creation between (1; 4) and (5; 8), separately. In the mentioned interactions we take into account spontaneous emission rate for atoms and field decay rate from the cavities as two important and unavoidable dissipation sources. In the continuation, we transfer the entanglement to the objective pair (1; 8) by two methods: i ) Bell state measurement (BSM), and ii ) cavity quantum electrodynamics (QED). The successfulness of our protocol is shown via the evaluation of concurrence as the well-established measure of entanglement between the two (far apart) qubits (1; 8). We also observe that, if one chooses the cavity and the atom such that holds, the effect of dissipations is effectively removed from the entanglement dynamics in our model. In this condition, the time evolutions of concurrence and success probability are regularly periodic. Also, concurrence and success probability reach to their maximum values in a large time interval by decreasing the detuning in the presence of dissipation.