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W2138792658 abstract "The energy transport process in natural-light-harvesting systems is investigated by solving the time-dependent Schrödinger equation for a source-network-drain model incorporating the effects of dephasing and dissipation, owing to coupling with the environment. In this model, the network consists of electronically coupled chromophores, which can host energy excitations (excitons) and are connected to source channels, from which the excitons are generated, thereby simulating exciton creation from sunlight. After passing through the network, excitons are captured by the reaction centers and converted into chemical energy. In addition, excitons can reradiate in green plants as photoluminescent light or be destroyed by nonphotochemical quenching (NPQ). These annihilation processes are described in the model by outgoing channels, which allow the excitons to spread to infinity. Besides the photoluminescent reflection, the NPQ processes are the main outgoing channels accompanied by energy dissipation and dephasing. From the simulation of wave-packet dynamics in a one-dimensional chain, it is found that, without dephasing, the motion remains superdiffusive or ballistic, despite the strong energy dissipation. At an increased dephasing rate, the wave-packet motion is found to switch from superdiffusive to diffusive in nature. When a steady energy flow is injected into a site of a linear chain, exciton dissipation along the chain, owing to photoluminescence and NPQ processes, is examined by using a model with coherent and incoherent outgoing channels. It is found that channel coherence leads to suppression of dissipation and multiexciton super-radiance. With this method, the effects of NPQ and dephasing on energy transfer in the Fenna-Matthews-Olson complex are investigated. The NPQ process and the photochemical reflection are found to significantly reduce the energy-transfer efficiency in the complex, whereas the dephasing process slightly enhances the efficiency. The calculated absorption spectrum reproduces the main features of the measured counterpart. As a comparison, the exciton dynamics are also studied in a linear chain of pigments and in a multiple-ring system of light-harvesting complexes II (LH2) from purple bacteria by using the Davydov D1 ansatz. It is found that the exciton transport shows superdiffusion characteristics in both the chain and the LH2 rings." @default.
W2138792658 created "2016-06-24" @default.
W2138792658 creator A5030697473 @default.
W2138792658 creator A5035534190 @default.
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W2138792658 date "2014-07-08" @default.
W2138792658 modified "2023-09-22" @default.
W2138792658 title "Dephasing and Dissipation in a Source-Drain Model of Light-Harvesting Systems" @default.
W2138792658 cites W1505159811 @default.
W2138792658 cites W1576724039 @default.
W2138792658 cites W1688719374 @default.
W2138792658 cites W1805686156 @default.
W2138792658 cites W1899574752 @default.
W2138792658 cites W1966386667 @default.
W2138792658 cites W1967846805 @default.
W2138792658 cites W1976721394 @default.
W2138792658 cites W1977825086 @default.
W2138792658 cites W1978547076 @default.
W2138792658 cites W1978618913 @default.
W2138792658 cites W1979364399 @default.
W2138792658 cites W1980799223 @default.
W2138792658 cites W1985042684 @default.
W2138792658 cites W1997741351 @default.
W2138792658 cites W2006315360 @default.
W2138792658 cites W2017271219 @default.
W2138792658 cites W2019663885 @default.
W2138792658 cites W2020347728 @default.
W2138792658 cites W2023813727 @default.
W2138792658 cites W2025447712 @default.
W2138792658 cites W2025525862 @default.
W2138792658 cites W2026354169 @default.
W2138792658 cites W2026766829 @default.
W2138792658 cites W2030274986 @default.
W2138792658 cites W2034481015 @default.
W2138792658 cites W2035838814 @default.
W2138792658 cites W2042487980 @default.
W2138792658 cites W2044133255 @default.
W2138792658 cites W2046604895 @default.
W2138792658 cites W2058427027 @default.
W2138792658 cites W2058468006 @default.
W2138792658 cites W2067930799 @default.
W2138792658 cites W2075358386 @default.
W2138792658 cites W2078196013 @default.
W2138792658 cites W2079079617 @default.
W2138792658 cites W2082171613 @default.
W2138792658 cites W2082497480 @default.
W2138792658 cites W2084288916 @default.
W2138792658 cites W2090061616 @default.
W2138792658 cites W2090813143 @default.
W2138792658 cites W2092312863 @default.
W2138792658 cites W2095471229 @default.
W2138792658 cites W2097552134 @default.
W2138792658 cites W2097668319 @default.
W2138792658 cites W2099681562 @default.
W2138792658 cites W2116928722 @default.
W2138792658 cites W2124122513 @default.
W2138792658 cites W2127296814 @default.
W2138792658 cites W2133257492 @default.
W2138792658 cites W2146818291 @default.
W2138792658 cites W2147766323 @default.
W2138792658 cites W2160091993 @default.
W2138792658 cites W2160690046 @default.
W2138792658 cites W2161324059 @default.
W2138792658 cites W2162328638 @default.
W2138792658 cites W2169578803 @default.
W2138792658 cites W2171373923 @default.
W2138792658 cites W2172244271 @default.
W2138792658 cites W2314969497 @default.
W2138792658 cites W2746718465 @default.
W2138792658 cites W379702399 @default.
W2138792658 cites W4238053576 @default.
W2138792658 cites W4246222558 @default.
W2138792658 doi "https://doi.org/10.1002/cphc.201402013" @default.
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