Temperature-independent almost perfect photon entanglement from quantum dots via the SUPER scheme

Thomas K. Bracht, Moritz Cygorek, Tim Seidelmann, Vollrath Martin Axt, and Doris E. Reiter
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Abstract

Entangled photon pairs are essential for quantum communication technology. They can be generated on-demand by semiconductor quantum dots, but several mechanisms are known to reduce the degree of entanglement. While some obstacles like the finite fine-structure splitting of the exciton states can currently be overcome, the excitation scheme itself can impair the entanglement fidelity. Here, we demonstrate that the swing-up of quantum emitter population (SUPER) scheme, using two red-detuned laser pulses applied to a quantum dot in a cavity, yields almost perfectly entangled photons. The entanglement remains robust against phonon influences even at elevated temperatures, due to decoupling of the excitation and emission process. With this achievement, quantum dots are ready to be used as entangled photon pair sources in applications requiring high degrees of entanglement up to temperatures of approximately 80 K.
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通过 SUPER 方案实现量子点与温度无关的近乎完美的光子纠缠
纠缠光子对对量子通信技术至关重要。半导体量子点可按需产生纠缠光子对,但已知有几种机制会降低纠缠程度。虽然目前可以克服一些障碍,如激子态的有限精细结构分裂,但激发方案本身也会损害纠缠保真度。在这里,我们证明了量子发射器群体摆动(SUPER)方案,即使用两个红色调谐激光脉冲对空腔中的量子点进行激发,可以产生几乎完美的纠缠光子。由于激发和发射过程解耦,即使在高温条件下,这种纠缠仍能抵御声子的影响。有了这一成果,量子点就可以作为纠缠光子对源,应用于对纠缠度要求较高的领域,最高温度可达约 80 K。
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