Lu Ying-Chih, Diau Eric Wei-Guang, Rau Hermann
Department of Applied Chemistry, Institute of Molecular Science, and Center for Interdisciplinary Molecular Science, National Chiao Tung University, Hsinchu 30010, Taiwan.
J Phys Chem A. 2005 Mar 17;109(10):2090-9. doi: 10.1021/jp044934b.
The ultrafast relaxation dynamics of two rotation-restricted (azobenzeno-2S-phane and azobenzeno-4S-phane) and one rotation-free (4,4'-dimethylazobenzene) azobenzene derivatives were investigated using femtosecond fluorescence up-conversion on both S(1)(n,pi) and S(2)(pi,pi) excitations. On S(2) excitation, pulse-limited kinetics with a decay coefficient of approximately 100 fs corresponding to ultrafast S(2) --> S(1) relaxation is found to be common for all molecules under investigation regardless of the molecular structure. This indicates that a direct rotational relaxation on the S(2) surface is unfavorable. On S(1) excitation, we observed biphasic fluorescence decay with a femtosecond component attributed to the decay of the Franck-Condon state prepared by excitation and a picosecond component attributed to the deactivation of the relaxed molecule on the S(1) surface. This picosecond component is slowed by at least a factor of 2 for the rotation-restricted 2S-bridged molecule compared to that of the rotation-free molecule; for the even stronger rotation-restricted azobenzeno-4S-phane, the decrease is by a factor of 10. These differences in deactivation suggest that the relaxed states and probably the trajectories for rotation-free and rotation-restricted molecules are different on the S(1) surface, which should be important for the quantum yield of photoisomerization.
使用飞秒荧光上转换技术,在S(1)(n,π)和S(2)(π,π)激发下,研究了两种旋转受限的(偶氮苯并-2S-环烷和偶氮苯并-4S-环烷)和一种无旋转的(4,4'-二甲基偶氮苯)偶氮苯衍生物的超快弛豫动力学。在S(2)激发下,发现对于所有研究的分子,无论其分子结构如何,具有约100 fs衰减系数的脉冲受限动力学对应于超快的S(2)→S(1)弛豫是常见的。这表明在S(2)表面上直接的旋转弛豫是不利的。在S(1)激发下,我们观察到双相荧光衰减,其中飞秒成分归因于激发制备的弗兰克-康登态的衰减,皮秒成分归因于S(1)表面上弛豫分子的失活。与无旋转分子相比,对于旋转受限的2S-桥连分子,这种皮秒成分至少减慢了2倍;对于旋转受限更强的偶氮苯并-4S-环烷,减少了10倍。这些失活差异表明,在S(1)表面上,无旋转和旋转受限分子的弛豫态以及可能的轨迹是不同的,这对于光异构化的量子产率应该是重要的。