Simulating photosynthetic energy transport on a photonic network

IF 6.6 1区 物理与天体物理 Q1 PHYSICS, APPLIED
Hao Tang, Xiao-Wen Shang, Zi-Yu Shi, Tian-Shen He, Zhen Feng, Tian-Yu Wang, Ruoxi Shi, Hui-Ming Wang, Xi Tan, Xiao-Yun Xu, Yao Wang, Jun Gao, M. S. Kim, Xian-Min Jin
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Abstract

Quantum effects in photosynthetic energy transport in nature, especially for the typical Fenna-Matthews-Olson (FMO) complexes, are extensively studied in quantum biology. Such energy transport processes can be investigated as open quantum systems that blend the quantum coherence and environmental noise, and have been experimentally simulated on a few quantum devices. However, the existing experiments always lack a solid quantum simulation for the FMO energy transport due to their constraints to map a variety of issues in actual FMO complexes that have rich biological meanings. Here we successfully map the full coupling profile of the seven-site FMO structure by comprehensive characterisation and precise control of the evanescent coupling of the three-dimensional waveguide array. By applying a stochastic dynamical modulation on each waveguide, we introduce the base site energy and the dephasing term in coloured noise to faithfully simulate the power spectral density of the FMO complexes. We show our photonic model well interprets the phenomena including reorganisation energy, vibrational assistance, exciton transfer and energy localisation. We further experimentally demonstrate the existence of an optimal transport efficiency at certain dephasing strength, providing a window to closely investigate environment-assisted quantum transport.

Abstract Image

模拟光子网络上的光合作用能量传输
量子生物学对自然界中光合作用能量传输的量子效应,特别是典型的芬纳-马修斯-奥尔森(FMO)复合物进行了广泛研究。这种能量传输过程可作为融合了量子相干性和环境噪声的开放量子系统进行研究,并已在一些量子设备上进行了实验模拟。然而,现有的实验始终缺乏对 FMO 能量传输的扎实量子模拟,原因是它们无法映射具有丰富生物学意义的实际 FMO 复合物中的各种问题。在这里,我们通过全面描述和精确控制三维波导阵列的蒸发耦合,成功绘制了七位 FMO 结构的完整耦合曲线。通过在每个波导上应用随机动态调制,我们在彩色噪声中引入了基点能量和去相项,从而忠实地模拟了 FMO 复合物的功率谱密度。我们的研究表明,我们的光子模型能很好地解释重组能量、振动辅助、激子转移和能量定位等现象。我们进一步通过实验证明,在一定的去相强度下存在最佳传输效率,这为密切研究环境辅助量子传输提供了一个窗口。
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来源期刊
npj Quantum Information
npj Quantum Information Computer Science-Computer Science (miscellaneous)
CiteScore
13.70
自引率
3.90%
发文量
130
审稿时长
29 weeks
期刊介绍: The scope of npj Quantum Information spans across all relevant disciplines, fields, approaches and levels and so considers outstanding work ranging from fundamental research to applications and technologies.
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