Rosenfeld Daniel E, Nishida Jun, Yan Chang, Gengeliczki Zsolt, Smith Brian J, Fayer Michael D
Department of Chemistry Stanford University, Stanford, CA 94305.
J Phys Chem C Nanomater Interfaces. 2012 Nov 8;116(44):23428-23440. doi: 10.1021/jp307677b.
The structural dynamics of thin films consisting of tricarbonyl (1,10-phenanthroline)rhenium chloride (RePhen(CO)(3)Cl) linked to an alkyl silane monolayer through a triazole linker synthesized on silica-on-calcium-fluoride substrates are investigated using ultrafast infrared (IR) techniques. Ultrafast 2D IR vibrational echo experiments and polarization selective heterodyne detected transient grating (HDTG) measurements, as well as polarization dependent FT-IR and AFM experiments are employed to study the samples. The vibrational echo experiments measure spectral diffusion, while the HDTG experiments measure the vibrational excited state population relaxation and investigate the vibrational transition dipole orientational anisotropy decay. To investigate the anticipated impact of vibrational excitation transfer, which can be caused by the high concentration of RePhen(CO)(3)Cl in the monolayer, a concentration dependence of the spectral diffusion is measured. To generate a range of concentrations, mixed monolayers consisting of both hydrogen terminated and triazole/RePhen(CO)(3)Cl terminated alkyl silanes are synthesized. It is found that the measured rate of spectral diffusion is independent of concentration, with all samples showing spectral diffusion of 37 ± 6 ps. To definitively test for vibrational excitation transfer, polarization selective HDTG experiments are conducted. Excitation transfer will cause anisotropy decay. Polarization resolved heterodyne detected transient grating spectroscopy is sensitive to anisotropy decay (depolarization) caused by excitation transfer and molecular reorientation. The HDTG experiments show no evidence of anisotropy decay on the appropriate time scale, demonstrating the absence of excitation transfer the RePhen(CO)(3)Cl. Therefore the influence of excitation transfer on spectral diffusion is inconsequential in these samples, and the vibrational echo measurements of spectral diffusion report solely on structural dynamics. A small amount of very fast (~2 ps time scale) anisotropy decay is observed. The decay is concentration independent, and is assigned to wobbling-in-a-cone orientational motions of the RePhen(CO)(3)Cl. Theoretical calculations reported previously for experiments on a single concentration of the same type of sample suggested the presence of some vibrational excitation transfer and excitation transfer induced spectral diffusion. Possible reasons for the experimentally observed lack of excitation transfer in these high concentration samples are discussed.
利用超快红外(IR)技术研究了由三羰基(1,10 - 菲咯啉)氯化铼(RePhen(CO)(3)Cl)通过三唑连接体与烷基硅烷单层相连组成的薄膜的结构动力学,该薄膜在氟化钙基底上的二氧化硅上合成。采用超快二维红外振动回波实验、偏振选择性外差检测瞬态光栅(HDTG)测量以及偏振相关傅里叶变换红外光谱(FT - IR)和原子力显微镜(AFM)实验来研究样品。振动回波实验测量光谱扩散,而HDTG实验测量振动激发态布居弛豫并研究振动跃迁偶极取向各向异性衰减。为了研究由单层中高浓度的RePhen(CO)(3)Cl可能引起的振动激发转移的预期影响,测量了光谱扩散的浓度依赖性。为了产生一系列浓度,合成了由氢封端和三唑/RePhen(CO)(3)Cl封端的烷基硅烷组成的混合单层。发现测量的光谱扩散速率与浓度无关,所有样品的光谱扩散均为37±6皮秒。为了明确测试振动激发转移,进行了偏振选择性HDTG实验。激发转移会导致各向异性衰减。偏振分辨外差检测瞬态光栅光谱对由激发转移和分子重新取向引起的各向异性衰减(去极化)敏感。HDTG实验表明在适当的时间尺度上没有各向异性衰减的证据,证明不存在RePhen(CO)(3)Cl的激发转移。因此,在这些样品中激发转移对光谱扩散的影响无关紧要,光谱扩散的振动回波测量仅反映结构动力学。观察到少量非常快(约2皮秒时间尺度)的各向异性衰减。这种衰减与浓度无关,归因于RePhen(CO)(3)Cl的锥内摆动取向运动。先前针对相同类型样品单一浓度的实验报道的理论计算表明存在一些振动激发转移和激发转移诱导的光谱扩散。讨论了在这些高浓度样品中实验观察到缺乏激发转移的可能原因。