Subexponential rate versus distance with time-multiplexed quantum repeaters

TL;DR

This paper demonstrates that time-multiplexed quantum repeaters can achieve sub-exponential rate decay over distance, significantly improving quantum communication efficiency compared to traditional methods.

Contribution

The introduction of temporal multiplexing in quantum repeaters enables sub-exponential rate scaling, surpassing previous exponential decay limitations without quantum error correction.

Findings

Time multiplexing achieves rate scaling of e^{-t√(αL)}.

Switch losses degrade the rate, reverting to exponential decay.

Quantum memory decoherence impacts performance more than switch losses.

Abstract

Quantum communications capacity using direct transmission over length-$L$ optical fiber scales as $R \sim e^{-\alpha L}$, where $\alpha$ is the fiber's loss coefficient. The rate achieved using a linear chain of quantum repeaters equipped with quantum memories, probabilistic Bell state measurements (BSMs) and switches used for spatial multiplexing, but no quantum error correction, was shown to surpass the direct-transmission capacity. However, this rate still decays exponentially with the end-to-end distance, viz., $R \sim e^{-s{\alpha L}}$, with $s < 1$. We show that the introduction of temporal multiplexing - i.e., the ability to perform BSMs among qubits at a repeater node that were successfully entangled with qubits at distinct neighboring nodes at {\em different} time steps - leads to a sub-exponential rate-vs.-distance scaling, i.e., $R \sim e^{-t\sqrt{\alpha L}}$, which is not attainable with just spatial or spectral multiplexing. We evaluate analytical upper and lower bounds to this rate, and obtain the exact rate by numerically optimizing the time-multiplexing block length and the number of repeater nodes. We further demonstrate that incorporating losses in the optical switches used to implement time multiplexing degrades the rate-vs.-distance performance, eventually falling back to exponential scaling for very lossy switches. We also examine models for quantum memory decoherence and describe optimal regimes of operation to preserve the desired boost from temporal multiplexing. Quantum memory decoherence is seen to be more detrimental to the repeater's performance over switching losses.