Bašinskaitė Eglė, Butkus Vytautas, Abramavicius Darius, Valkunas Leonas
Department of Theoretical Physics, Faculty of Physics, Vilnius University, Sauletekio 9-III, 10222, Vilnius, Lithuania.
Photosynth Res. 2014 Jul;121(1):95-106. doi: 10.1007/s11120-014-0002-z. Epub 2014 Apr 17.
It is already well established that the high-frequency intramolecular vibrations are responsible for many observed dynamic phenomena in linear and nonlinear electronic spectroscopy such as the spectral lineshape formation, the transition dipole moment, the lifetime borrowing, and vibrational and mixed coherence beats. All these implications together with the vibronic enhancement of the energy and charge transfer can be explained by the vibronic molecular exciton theory and are highly relevant for the description of the spectral dynamics in photosynthetic pigment-protein complexes. In this paper, a few critical points of the vibronic theory application to linear and nonlinear signals are discussed. Models, which differ in the selection and truncation of molecular basis, are compared by analyzing the energy spectrum and exciton-vibrational dynamics in the presence of the energetic disorder. The limits of the widely used one-particle approximation are defined.
高频分子内振动导致了线性和非线性电子光谱中许多观测到的动态现象,如光谱线形的形成、跃迁偶极矩、寿命借用以及振动和混合相干拍,这一点已经得到了充分证实。所有这些影响以及能量和电荷转移的振动电子增强效应都可以用振动电子分子激子理论来解释,并且对于描述光合色素 - 蛋白质复合物中的光谱动力学高度相关。在本文中,讨论了振动电子理论应用于线性和非线性信号的几个关键点。通过分析存在能量无序情况下的能谱和激子 - 振动动力学,比较了在分子基的选择和截断方面不同的模型。定义了广泛使用的单粒子近似的局限性。