Department of Chemistry, Graduate School of Science, Osaka City University, Sumiyosi-ku, Osaka 558-8585, Japan.
J Phys Chem A. 2009 Aug 27;113(34):9521-6. doi: 10.1021/jp9042717. Epub 2009 Aug 5.
In high-spin chemistry, random-orientation fine-structure (FS) electron spin resonance (ESR) spectroscopy entertains advantages as the most facile and convenient method to identify high-spin systems, as frequently reported in the literature. Random-orientation ESR spectroscopy applicable to organic high-spin entities can date back to the Wasserman and co-workers' attempt on the first spin-quintet dicarbene, m-phenylenebis(phenylmethlene) (m-PBPM), in the 2-MTHF glass in 1963 and 1967, following their successful work on randomly oriented triplet-state ESR spectroscopy. The FS ESR spectrum of m-PBPM in the 2-MTHF glass, however, has never fully been analyzed due to a peculiar line-broadening appearing at many canonical peaks. Organic high-spin spectra from most quintet dinitrenes also suffer from similar phenomena. Seemingly intrinsic line-diffusing or -broadening phenomena adversely affect the reliable determination of FS parameters for organic high-spin entities in rigid glasses. In high-spin chemistry, the line-broadening has been an obstacle that masks key FS transitions in many cases. Thus, both the origin of the broadening and the comprehensive spectral analysis have been a long-standing issue. In this report, we examine the origin of the line-broadening appearing in the FS ESR spectra, illustrated by a comprehensive spectral analysis for m-PBPM in the quintet ground state and the first-documented quintet-state dinitrene, m-phenylenebis(nitrene) (m-PBN) in the 2-MTHF glass. A complete analysis of the random-orientation FS spectra from m-PBPM diluted in the benzophenone crystal has shown that the g-anisotropy of m-PBPM is not prominent. Also the higher-order FS terms such as S(i)(2)S(j)(2) group-theoretically allowed for S = 2 are not necessary in spite of the argument for a hydrocarbon-based tetraradical (S = 2) in the ground state. Our new approach to the line-broadening analysis invokes both exact analytical solutions for the resonance fields of canonical peaks and the magnetic-parameters gradient method. The D- and E-values of m-PBPM acquired by the spectral simulation in this study give different molecular structures of the quintet dicarbene in the benzophenone crystal lattice (D = +0.0703(0) cm(-1), E = +0.0212(0) cm(-1)) and in the 2-MTHF glass (D = +0.0780(0) cm(-1), E = +0.0221(0) cm(-1)). Microscopic origins of the line-broadening observed for high-spin oligocarbenes or oligonitrenes generated by photolysis in organic glasses have been proposed.
在高自旋化学中,随机取向精细结构(FS)电子自旋共振(ESR)光谱作为识别高自旋体系的最简便、最方便的方法,具有优势,这在文献中经常报道。适用于有机高自旋实体的随机取向 ESR 光谱可以追溯到 Wasserman 及其同事于 1963 年和 1967 年在 2-MTHF 玻璃中首次尝试自旋 Quintet 二碳烯,间苯撑双(亚甲基)(m-PBPM),继他们成功地进行了随机取向三重态 ESR 光谱研究之后。然而,由于在许多规范峰处出现奇特的线宽,m-PBPM 在 2-MTHF 玻璃中的 FS ESR 光谱从未得到充分分析。大多数 Quintet dinitrenes 的有机高自旋光谱也存在类似的现象。看似内在的线扩散或线宽现象会对刚性玻璃中有机高自旋实体的 FS 参数的可靠确定产生不利影响。在高自旋化学中,线宽一直是许多情况下掩盖关键 FS 跃迁的障碍。因此,线宽的起源和综合光谱分析一直是一个长期存在的问题。在本报告中,我们通过对 Quintet 基态的 m-PBPM 和第一份记录的 Quintet 态二亚胺,间苯撑双(亚胺)(m-PBN)在 2-MTHF 玻璃中的综合光谱分析,研究了出现在 FS ESR 光谱中的线宽的起源。对 m-PBPM 在二苯甲酮晶体中的稀释进行的随机取向 FS 光谱的完整分析表明,m-PBPM 的 g 各向异性不明显。尽管有人认为基态为碳氢化合物的四自由基(S = 2),但即使考虑到 S = 2 的高阶 FS 项,如 S(i)(2)S(j)(2)群理论上允许的项也不是必需的。我们对线宽分析的新方法同时调用了规范峰共振场的精确解析解和磁参数梯度法。本研究中通过光谱模拟获得的 m-PBPM 的 D 和 E 值给出了在二苯甲酮晶格(D = +0.0703(0)cm(-1),E = +0.0212(0)cm(-1))和 2-MTHF 玻璃(D = +0.0780(0)cm(-1)中 Quintet 二碳烯的不同分子结构,E = +0.0221(0)cm(-1))。提出了通过有机玻璃光解产生的高自旋寡碳烯或寡亚氮烯的线宽观察到的微观起源。
