School of Chemistry, University of Bristol, Cantocks Close, Bristol BS8 1TS, United Kingdom.
J Chem Phys. 2009 Nov 7;131(17):174305. doi: 10.1063/1.3257681.
The photophysical properties of porphyrins have relevance for their use as light-activated drugs in cancer treatment and sensitizers in solid-state solar cells. However, the appearance of their UV-visible spectra is usually explained inadequately by qualitative molecular-orbital theories. We intend to gain a better insight into the intense absorption bands, and excited-state dynamics, that make porphyrins appropriate for both of these applications by gradually building toward an understanding of the macrocyclic structure, starting with studies of smaller pyrrolic subunits. We have recorded the (1+1) and (2+1) resonance-enhanced multiphoton ionization (REMPI) spectra of pyrrole and 2,5-dimethylpyrrole between 25 600 cm(-1) (390 nm) and 48 500 cm(-1) (206 nm). We did not observe a (1+1) REMPI signal through the optically bright (1)B(2) (pipi( *)) and (1)A(1) (pipi( *)) states in pyrrole due to ultrafast deactivation via conical intersections with the dissociative (1)A(2) (pisigma( *)) and (1)B(1) (pisigma( *)) states. However, we did observe (2+1) REMPI through Rydberg states with a dominant feature at 27 432 cm(-1) (two-photon energy, 54 864 cm(-1)) assigned to a 3d<--pi transition. In contrast, 2,5-dimethylpyrrole has a broad and structured (1+1) REMPI spectrum between 36 000 and 42 500 cm(-1) as a result of vibronic transitions to the (1)B(2) (pipi( *)) state, and it does not show the 3d<--pi Rydberg transition via (2+1) REMPI. We have complemented the experimental studies by a theoretical treatment of the excited states of both molecules using time-dependent density functional theory (TD-DFT) and accounted for the contrasting features in the spectra. TD-DFT modeled the photochemical activity of both the optically dark (1)pisigma( *) states (dissociative) and optically bright (1)pipi( *) states well, predicting the barrierless deactivation of the (1)B(2) (pipi( *)) state of pyrrole and the bound minimum of the (1)B(2) (pipi( *)) state in 2,5-dimethylpyrrole. However, the quantitative agreement between vibronic transition energies and the excited-state frequencies calculated by TD-DFT was hampered by inaccurate modeling of Rydberg orbital mixing with the valence states, caused by the lack of an asymptotic correction to the exchange-correlation functionals used.
卟啉的光物理性质与其在癌症治疗中的光激活药物和固态太阳能电池中的敏化剂的应用有关。然而,定性分子轨道理论通常不能充分解释其紫外可见光谱的出现。我们打算通过逐渐了解大环结构,从对较小的吡咯亚基的研究开始,更好地了解使卟啉适用于这两种应用的强烈吸收带和激发态动力学。我们已经记录了吡咯和 2,5-二甲基吡咯在 25600 cm(-1)(390nm)至 48500 cm(-1)(206nm)之间的(1+1)和(2+1)共振增强多光子电离(REMPI)光谱。由于超快通过与解离的(1)A(2)(pisigma( *))和(1)B(1)(pisigma( *))态的锥形交叉而通过非辐射去活,我们没有观察到吡咯中通过光学亮态(1)B(2)(pipi( *))和(1)A(1)(pipi( *))态的(1+1)REMPI 信号。然而,我们确实通过 Rydberg 态观察到(2+1)REMPI,其主要特征位于 27432cm(-1)(双光子能量,54864cm(-1)),分配给 3d<--pi 跃迁。相比之下,由于向(1)B(2)(pipi( *))态的振动态跃迁,2,5-二甲基吡咯具有宽而结构化的(1+1)REMPI 光谱,范围为 36000cm(-1)至 42500cm(-1),并且不通过(2+1)REMPI 显示 3d<--pi Rydberg 跃迁。我们通过使用时间相关密度泛函理论(TD-DFT)对两种分子的激发态进行理论处理,并解释了光谱中的对比特征,补充了实验研究。TD-DFT 很好地模拟了两种光化学活性的(1)pisi( *)态(解离的)和光致亮的(1)pipi( *)态,预测了吡咯的(1)B(2)(pipi( *))态无势垒失活和 2,5-二甲基吡咯中(1)B(2)(pipi( *))态的束缚能。然而,由于用于交换相关泛函的缺乏渐近校正,与价态的 Rydberg 轨道混合的不准确建模,阻碍了振动态能量与通过 TD-DFT 计算的激发态频率之间的定量一致性。
