A stochastic reorganizational bath model for electronic energy transfer

Fujita, Takatoshi; Huh, Joonsuk; Aspuru‐Guzik, Alán

doi:10.1063/1.4883862

Cited by 8 publications

(13 citation statements)

References 91 publications

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“…Within our simulations the quantum and classical subsystems are coupled to each other in a self-consistent way using the surface-hopping method. − This method accounts for the Stokes shift and leads to a Boltzmann distribution within the quantum system in equilibrium, which is crucial when dealing with electronic systems where the energy separation between states is comparable to or larger than k B T . − Semiempirical electronic structure calculations usually assume a ground-state trajectory for the classical system and are unable to describe these effects. Some exceptions are refs and . The method presented here can readily be applied to other light harvesting systems like LH1, photosystem II, and FMO.…”

Section: Introductionmentioning

confidence: 99%

Atomistic Modeling of Two-Dimensional Electronic Spectra and Excited-State Dynamics for a Light Harvesting 2 Complex

et al. 2015

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The Light Harvesting 2 (LH2) complex is a vital part of the photosystem of purple bacteria. It is responsible for the absorption of light and transport of the resulting excitations to the reaction center in a highly efficient manner. A general description of the chromophores and the interaction with their local environment is crucial to understand this highly efficient energy transport. Here we include this interaction in an atomistic way using mixed quantum-classical (molecular dynamics) simulations of spectra. In particular, we present the first atomistic simulation of nonlinear optical spectra for LH2 and use it to study the energy transport within the complex. We show that the frequency distributions of the pigments strongly depend on their positions with respect to the protein scaffold and dynamics of their local environment. Furthermore, we show that although the pigments are closely packed the transition frequencies of neighboring pigments are essentially uncorrelated. We present the simulated linear absorption spectra for the LH2 complex and provide a detailed explanation of the states responsible for the observed two-band structure. Finally, we discuss the energy transfer within the complex by analyzing population transfer calculations and 2D spectra for different waiting times. We conclude that the energy transfer from the B800 ring to the B850 ring is mediated by intermediate states that are delocalized over both rings, allowing for a stepwise downhill energy transport.

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Section: Introductionmentioning

confidence: 99%

Atomistic Modeling of Two-Dimensional Electronic Spectra and Excited-State Dynamics for a Light Harvesting 2 Complex

et al. 2015

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“…Another problem is the use of the Ehrenfest-type approach, where the equilibrium populations cannot be reproduced [33,65]. Although this deficiency would deteriorate the electron-transfer time scales, the initial coherent dynamics can be well reproduced with the present method [35].…”

Section: B Excited-state Dynamics and Transient Absorption Spectramentioning

confidence: 96%

“…In this study, the quantum dynamics and spectroscopy were simulated by numerically integrating the time-dependent Schrödinger equation [32][33][34][35]. The time-dependent Hamiltonian includes the time-independent and time-dependent parts as, H(t) = H e/ f + H B (t).…”

Section: B Quantum Dynamics and Spectroscopymentioning

confidence: 99%

“…In the present method, the parameters for the nuclear motion are given by the λ m , T , and the inverse relaxation time (Γ). The population dynamics and optical response functions are obtained from the ensemble averages of the trajectories, which are determined by the time-dependent Schrödinger equation coupled with Langevin equation for the diagonal energy fluctuations [35].…”

Section: B Quantum Dynamics and Spectroscopymentioning

confidence: 99%

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Ab Initio Study of Charge Separation Dynamics and Pump–Probe Spectroscopy in the P3HT/PCBM Blend

Fujita

Hoshi

2023

Preprint

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We develop a computational method for excited-state dynamics and time-resolved spectroscopy signals in molecular aggregates, on the basis of ab initio excited-state calculations. As an application, we consider the charge separation dynamics and pump--probe spectroscopy in the amorphous P3HT/PCBM blend. To simulate quantum dynamics and time-resolved spectroscopy, the model Hamiltonian for single-excitation and double-excitation manifolds was derived on the basis of fragment-based excited-state calculations within the GW approximation and the Bethe--Salpeter equation. After elucidating the energetics of the electron--hole separation and examining linear absorption spectrum, we investigated the quantum dynamics of exciton and charge carriers in comparison with the pump--probe transient absorption spectra. In particular, we introduced the pump--probe excited-state absorption (ESA) anisotropy as a spectroscopic signature of charge carrier dynamics after exciton dissociation. We found that the charge separation dynamics can be probed by the pump--probe ESA anisotropy dynamics after charge-transfer excitations. The present study provides the fundamental information for understanding the experimental spectroscopy signals, by elucidating the relationship between the excited states, the exciton and charge carrier dynamics, and the time-resolved spectroscopy.

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“…The single vibration denoted by annihilation/creation operators a/a † coupled to the acceptor is a source of quantum noise and may coherently assist the excitation energy transfer [15]. The term δ(t) added to the site energy describes a classical Gaussian white noise source within the Haken-Strobl-Reinker model [20,[23][24][25], characterized by zero mean and variance σ 2 .…”

Section: A Dimeric Noisy Chromophore Donor-acceptor Systemmentioning

confidence: 99%

Interplay of vibration- and environment-assisted energy transfer

Li,

Ko,

Yang

et al. 2021

Preprint

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We study the interplay between two environmental influences on excited state energy transfer in photosynthetic light harvesting complexes, namely, vibrationally assisted energy transfer(VAET) and environment-assisted quantum transport (ENAQT), considering a dimeric chromophore donoracceptor model as a prototype for larger systems. We demonstrate how the basic features of the excitonic energy transfer are influenced by these two environments, both separately and together, with the environment being fully quantum in the case of VAET and treated in the Haken-Strobl-Reineker classical limit in the case of ENAQT. Our results reveal that in the weak noise regime, the presence of a classical noise source is detrimental to the energy transfer that is assisted by the exciton-vibration interactions intrinsic to VAET. However, the transfer efficiency can still be enhanced at much higher levels of classical noise.

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A stochastic reorganizational bath model for electronic energy transfer

Cited by 8 publications

References 91 publications

Atomistic Modeling of Two-Dimensional Electronic Spectra and Excited-State Dynamics for a Light Harvesting 2 Complex

Atomistic Modeling of Two-Dimensional Electronic Spectra and Excited-State Dynamics for a Light Harvesting 2 Complex

Ab Initio Study of Charge Separation Dynamics and Pump–Probe Spectroscopy in the P3HT/PCBM Blend

Interplay of vibration- and environment-assisted energy transfer

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