Stabilizing Remote Entanglement via Waveguide Dissipation

PRX Quantum Pub Date : 2024-09-06 DOI:10.1103/prxquantum.5.030346

Parth S. Shah, Frank Yang, Chaitali Joshi, Mohammad Mirhosseini

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Abstract

Distributing entanglement between remote sites is integral to quantum networks. Here, we demonstrate the autonomous stabilization of remote entanglement between a pair of noninteracting superconducting qubits connected by an open waveguide on a chip. In this setting, the interplay between a classical continuous drive—supplied through the waveguide—and dissipation into the waveguide stabilizes the qubit pair in a dark state, which, asymptotically, takes the form of a Bell state. We use field-quadrature measurements of the photons emitted to the waveguide to perform quantum state tomography on the stabilized states, where we find a concurrence of

{0.504}_{- 0.029}^{+ 0.007}

in the optimal setting with a stabilization time constant of

56 \pm 4

ns. We examine the imperfections within our system and discuss avenues for enhancing fidelities and achieving scalability in future work. The decoherence-protected steady-state remote entanglement offered via dissipative stabilization may find applications in distributed quantum computing, sensing, and communication.

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通过波导耗散稳定远程纠缠

在远程站点之间分配纠缠是量子网络不可或缺的一部分。在这里，我们展示了通过芯片上的开放波导连接的一对非相互作用超导量子比特之间远程纠缠的自主稳定。在这种情况下，通过波导提供的经典连续驱动力与波导中的耗散之间的相互作用，使量子比特对稳定在暗态，渐进地呈现出贝尔态的形式。我们利用对发射到波导的光子的场正交测量，对稳定态进行量子态层析成像，发现在稳定时间常数为 56±4 ns 的最佳设置下，并发度为 0.504-0.029+0.007。我们研究了系统中的不完善之处，并讨论了在未来工作中提高保真度和实现可扩展性的途径。通过耗散稳定提供的退相干保护稳态远程纠缠可能会在分布式量子计算、传感和通信中得到应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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