Optimal initialization of a quantum system for an efficient coherent energy transfer

Author(s)

Cao, Jianshu

Abstract

For an energy transfer network, the irreversible depletion of excited electron energy occurs through either an efficient flow into an outer energy sink or an inefficient decay. With a small decay rate, the energy transfer efficiency is quantitatively reflected by the average life time of excitation energy before being trapped in the sink where the decay process is omitted. In the weak dissipation regime, the trapping time is analyzed within the exciton population subspace based on the secular Redfield equation. The requirement of the noise-enhanced energy transfer is obtained, where the trapping time follows an exact or approximate 1/Γ-scaling of the dissipation strength Γ. On the opposite side, optimal initial system states are conceptually constructed to suppress the 1/Γ-scaling of the trapping time and maximize the coherent transfer efficiency. Our theory is numerically testified in four models, including a biased two-site system, a symmetric three-site branching system, a homogeneous one-dimensional chain, and an 8-chromophore FMO protein complex. ©2018

Date issued

2018

URI

https://hdl.handle.net/1721.1/124811

Department

Massachusetts Institute of Technology. Department of Chemistry

Journal

Chinese journal of chemical physics

Publisher

AIP Publishing

Citation

Gong,Zhi-hao, Zhou-fei Tang, Jian-shu Cao, and Jianlan Wu, "Optimal initialization of a quantum system for an efficient coherent energy transfer." Chinese journal of chemical physics 31, 31 (2018): no. 421 doi 10.1063/1674-0068/31/CJCP1804068 ©2018 Author(s)

Version: Final published version

ISSN

2327-2244

1674-0068