物理
量子纠缠
量子力学
电子
库珀对
弗洛奎特理论
量子计算机
量子
虚假关系
拓扑(电路)
计算机科学
电气工程
非线性系统
机器学习
工程类
作者
Bruno Bertin-Johannet,Laurent Raymond,Flavio Ronetti,Jérôme Rech,Thibaut Jonckheere,Benoît Grémaud,Thierry Martin
摘要
We propose a source of purely electronic energy-entangled states implemented in a solid-state system with potential applications in quantum information protocols based on electrons. The proposed device relies on the standard tools of electron quantum optics and exploits entanglement of the Cooper pairs of a BCS superconductor. The latter is coupled via an adjustable quantum point contact to two opposite spin-polarized electron wave-guides, which are driven by trains of Lorentzian pulses. This specific choice for the drive is crucial to inject purely electronic entangled states devoid of spurious electron–hole pairs. In the Andreev regime, a perturbative calculation in the tunnel coupling confirms that entangled electrons states are generated at the output of the normal side. For arbitrary tunnel coupling and for a periodic drive, direct current and noise (auto and cross correlations) are computed numerically using a Keldysh–Nambu–Floquet formalism. Importantly, for a periodic drive, the production of these states can be controlled in time, thus implementing an on-demand source of entangled states. We exploit realistic experimental parameters for our device to identify its optimal functioning point.
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