On-chip microwave coherent source with in-situ control of the photon number distribution

arXiv - PHYS - Other Condensed Matter Pub Date : 2024-06-15 DOI:arxiv-2406.10597

Pasquale Mastrovito, Halima Giovanna Ahmad, Martina Esposito, Davide Massarotti, Francesco Tafuri

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Abstract

Coherent photon sources are key elements in different applications, ranging from quantum sensing to quantum computing. In the context of circuit quantum electrodynamics, there have been multiple proposals for potential coherent sources of photons, but a well established candidate is still missing. The possibility of designing and engineering superconducting circuits behaving like artificial atoms supports the realization of quantum optics protocols, including microwave photons generation. Here we propose and theoretically investigate a new design that allows a tunable photon injection directly on-chip. The scheme is based on initiating a population inversion in a superconducting circuit that will act as the photon source of one or multiple target resonators. The key novelty of the proposed layout consists in replacing the usual capacitive link between the source and the target cavity with a tunable coupler, with the advantage of having on-demand control on the injected steady-state photons. We validate the dynamical control of the generated coherent states under the effect of an external flux threading the tunable coupler and discuss the possibility of employing this scheme also in the context of multiple bosonic reservoirs.

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现场控制光子数量分布的片上微波相干源

相干光子源是从量子传感到量子计算等不同应用中的关键要素。在电路量子电动力学的背景下，已经有多个关于潜在相干光子源的建议，但仍然缺少一个成熟的候选光子源。超导电路的设计和工程表现类似于人造原子，这种可能性支持量子光学协议的实现，包括微波光子的产生。在这里，我们提出并从理论上研究了一种新设计，它可以直接在芯片上实现可调光子注入。该方案的基础是在超导电路中启动种群反转，该电路将充当一个或多个目标谐振器的光子源。拟议布局的主要新颖之处在于用不可耦合器取代了光源和目标腔体之间通常的电容链路，其优势在于可对注入的稳态光子进行按需控制。我们验证了在可调耦合器外部通量的作用下对所产生相干态的动态控制，并讨论了在多个玻色储层的背景下采用这种方案的可能性。

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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arXiv - PHYS - Other Condensed Matter

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