Improving a quantum-dot-based single-photon source with continuous measurements

Anirudh Lanka, Todd Brun
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Abstract

We propose a technique to improve the probability of single-photon emission with an electrically pumped quantum dot in an optical microcavity by continuously monitoring the dot's energy state and using feedback to control when to stop pumping. The goal is to boost the probability of single-photon emission while bounding the probability of two or more photons. We model the system by a stochastic master equation that includes postmeasurement operations. Ideally, feedback should be based on the entire continuous measurement record, but in practice, it may be difficult to do such processing in real time. We show that even a simple threshold-based feedback scheme using measurements at a single time can improve performance over deterministic (open-loop) pumping. This technique is particularly useful for strong dot-cavity coupling with lower rates of pumping, as can be the case for electrical pumping. It is also numerically tractable since we can perform ensemble averaging with a single master equation rather than averaging over a large number of quantum trajectories.
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改进基于量子点的连续测量单光子源
本文提出了一种提高光微腔中电泵浦量子点单光子发射概率的技术,该技术通过连续监测量子点的能量状态并使用反馈控制何时停止泵浦来提高单光子发射概率。目标是提高单光子发射的概率,同时限制两个或更多光子发射的概率。我们用随机主方程对系统建模,其中包括测量后的操作。理想情况下,反馈应该基于整个连续的测量记录,但在实践中,可能很难实时地进行这样的处理。我们表明,即使是使用单次测量的简单的基于阈值的反馈方案也可以提高确定性(开环)泵送的性能。这种技术对于低泵送速率的强点腔耦合特别有用,就像电泵送一样。它在数值上也是易于处理的,因为我们可以用单个主方程执行集合平均,而不是对大量量子轨迹进行平均。
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