The impact of multimode sources on DLCZ type quantum repeaters

TL;DR

This paper analyzes how multimode emission from SPDC sources affects DLCZ-based quantum repeaters, optimizing parameters for high-fidelity entanglement over long distances under experimental constraints.

Contribution

It provides a detailed analysis of multimode effects in SPDC sources for DLCZ quantum repeaters and identifies optimal driving parameters for different operational regimes.

Findings

Narrow laser pulses improve entanglement fidelity but require high peak intensity.

Optimal pulse widths depend on swap depth and experimental limitations.

Acceptance window optimization enhances entanglement success probability.

Abstract

Long distance entanglement generation at a high rate is a major quantum technological goal yet to be fully realized, with the promise of many interesting applications, such as secure quantum computing on remote servers and quantum cryptography. One possible implementation is using a variant of the DLCZ-scheme by combining atomic-ensemble memories and linear optics with spontaneous parametric down conversion (SPDC) sources. As we edge closer to the realization of such a technology, the complete details of the underlying components become crucial. In this paper we consider the impact of the multimode emission from the SPDC source on quantum repeaters based on the DLCZ-scheme. We consider two cases, driving the SPDC using short Gaussian pulses and continuously. For pulsed driving, we find that the use of very narrow laser pulses to drive SPDC source is crucial to obtain high fidelity end-to-end entangled states but this puts demands on the peak intensity. By introducing a maximally allowed laser intensity, we find optimal pulse widths for each swap depth. For continuous driving, we find the temporal acceptance window of clicks relative to the heralding time to be a crucial parameter, and we can similarly optimize the acceptance window for each swap depth. For both cases, we thus identify optimal parameters given experimental limitations and aims. We have thus provided helpful knowledge towards the realization of long distance entanglement generation using the DLCZ-scheme.