Examining the quantum signatures of optimal excitation energy transfer

Jonah S. Peter, Raphael Holzinger, Stefan Ostermann, Susanne F. Yelin
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Abstract

The transport and capture of photo-induced electronic excitations is of fundamental interest to the design of energy efficient quantum technologies and to the study of potential quantum effects in biology. Using a simple quantum optical model, we examine the influence of coherence, entanglement, and cooperative dissipation on the transport and capture of excitation energy. We demonstrate that the rate of energy extraction is optimized under conditions that minimize the quantum coherence and entanglement of the system, which is a consequence of spontaneous parity time-reversal symmetry breaking. We then examine the effects of vibrational disorder and show that dephasing can be used to enhance the transport of delocalized excitations in settings relevant to biological photosynthesis. Our results highlight the rich, emergent behavior associated with the quantum-to-classical transition with relevance to the design of room-temperature quantum devices.

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研究最佳激发能量转移的量子特征
光诱导电子激发的传输和捕获对于设计高能效量子技术和研究生物学中的潜在量子效应具有重要意义。我们利用一个简单的量子光学模型,研究了相干性、纠缠和协同耗散对激发能量的传输和捕获的影响。我们证明,在系统的量子相干性和纠缠最小化的条件下,能量提取率是最优的,这是自发奇偶性时间反向对称性破缺的结果。然后,我们研究了振动无序的影响,并表明在与生物光合作用相关的环境中,可以利用去相位来增强脱局域激元的传输。我们的研究结果凸显了量子到经典转变过程中丰富的新兴行为,与室温量子器件的设计息息相关。
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