Application of two-dimensional optical spectroscopy: from ultrafast spectral diffusion to Lewis basicity

Abstract

Two-dimensional optical spectroscopy (2DOS) is the optical version of the well-established 2D-NMR technique, e.g., COSY. With time resolution in the femtosecond regime, 2DOS is widely used to resolve the ultrafast frequency modulation dynamics, such as spectral diffusion, in various vibrational [1-2] and electronic [3-4] systems. Chlorophylls (Chls) a and b are two main types of photosynthetic pigments responsible for the light-harvesting and energy regulation of green plants on Earth. Here, we employ 2DOS to track the time evolution of the 2D peakshape (Fig. 1) and resolve the ultrafast spectral diffusion dynamics of the Chl Q y transition in various organic solvents. The obtained results suggest that Chls exhibit three different relaxation dynamics with the timescales of sub-picosecond (sub-ps), several ps and tens to hundreds of ps. The correlation between spectral diffusion timescales and the solvents’ Lewis basicity, together with the support of ab initio time-dependent density functional theory (TDDFT) calculations indicates that we are probing directly the the dative bond the solvent’s lone pair and the electrophilic Mg 2+ center of Chls. bond the solvent Lewis basicity. a time-resolved molecular chemical property – Lewis basicity.