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Autores principales: Tang, Hao, Shang, Xiao-Wen, Shi, Zi-Yu, He, Tian-Shen, Feng, Zhen, Wang, Tian-Yu, Shi, Ruoxi, Wang, Hui-Ming, Tan, Xi, Xu, Xiao-Yun, Wang, Yao, Gao, Jun, Kim, M. S., Jin, Xian-Min
Formato: Preprint
Publicado: 2023
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Acceso en línea:https://arxiv.org/abs/2311.02020
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author Tang, Hao
Shang, Xiao-Wen
Shi, Zi-Yu
He, Tian-Shen
Feng, Zhen
Wang, Tian-Yu
Shi, Ruoxi
Wang, Hui-Ming
Tan, Xi
Xu, Xiao-Yun
Wang, Yao
Gao, Jun
Kim, M. S.
Jin, Xian-Min
author_facet Tang, Hao
Shang, Xiao-Wen
Shi, Zi-Yu
He, Tian-Shen
Feng, Zhen
Wang, Tian-Yu
Shi, Ruoxi
Wang, Hui-Ming
Tan, Xi
Xu, Xiao-Yun
Wang, Yao
Gao, Jun
Kim, M. S.
Jin, Xian-Min
contents 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 noises, 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 characterization 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 colored noises to faithfully simulate the power spectral density of the FMO complexes. We show our photonic model well interprets the issues including the reorganization energy, vibrational assistance, exciton transfer and energy localization. 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.
format Preprint
id arxiv_https___arxiv_org_abs_2311_02020
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Simulating Photosynthetic Energy Transport on a Photonic Network
Tang, Hao
Shang, Xiao-Wen
Shi, Zi-Yu
He, Tian-Shen
Feng, Zhen
Wang, Tian-Yu
Shi, Ruoxi
Wang, Hui-Ming
Tan, Xi
Xu, Xiao-Yun
Wang, Yao
Gao, Jun
Kim, M. S.
Jin, Xian-Min
Quantum Physics
Biological Physics
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 noises, 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 characterization 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 colored noises to faithfully simulate the power spectral density of the FMO complexes. We show our photonic model well interprets the issues including the reorganization energy, vibrational assistance, exciton transfer and energy localization. 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.
title Simulating Photosynthetic Energy Transport on a Photonic Network
topic Quantum Physics
Biological Physics
url https://arxiv.org/abs/2311.02020