Department of Precision Science and Technology, Graduate School of Engineering, Osaka University, 2-1 Yamada-oka Suita, Osaka 565-0871, Japan.
Phys Chem Chem Phys. 2019 Apr 21;21(15):7973-7988. doi: 10.1039/c8cp05016c. Epub 2019 Mar 29.
This work presents an interpretation of the origin of changes in absorption spectra upon one-electron oxidation and reduction of two ruthenium polypyridyl complexes based on a combination of UV-Vis spectroelectrochemical experiments and theoretical calculations using the Gaussian 09 program. A bis-chelating ligand containing a p-bromobenzoylthiourea unit connected to 1,10-phenanthroline (phen-p-BrBT) has been prepared. Complexation of phen-p-BrBT to ruthenium bis-diimine centres, Ru(N-N) [N-N = 2,2'-bipyridine (bpy) or 1,10-phenanthroline (phen)], affords octahedral Ru(ii) tris-diimine complexes that are synthesised and structurally characterised. The two complexes exhibit similar MLCT bands and electronic energy levels owing to the similar electronic structures of the bpy and phen ligands. However, [Ru(phen)(phen-p-BrBT)] exhibits a slightly broader visible region MLCT (metal-to-ligand-charge transfer) band than [Ru(bpy)(phen-p-BrBT)] as expected from a slightly more delocalised π-electron system in the phen diimine ligands. In addition, the π→π* absorption in the UV is blue-shifted for [Ru(phen)(phen-p-BrBT)] relative to that for [Ru(bpy)(phen-p-BrBT)], because of greater stabilisation of the bpy HOMO relative to that of phen. The extra C-C bond in phen produces greater delocalisation of electron density leading to a blue-shift in the π→π* transition. The MLCT band is blue-shifted and diminished in intensity upon oxidation due to stabilisation of the Ru d-orbitals by removal of one electron. A new broad absorption band appears in the UV region upon reduction. The new transition is attributed to a blue-shift of the first MLCT transition for [Ru(bpy)(phen-p-BrBT)] and a red-shift of the second MLCT transition for [Ru(phen)(phen-p-BrBT)]. The new transitions originate from destabilisation or stabilisation of the ligand LUMO orbitals relative to the Ru d-orbitals. A red-shift of the UV band in the initial complex also contributes to the new band produced upon reduction of [Ru(bpy)(phen-p-BrBT)]. The new band does not involve an n(C[double bond, length as m-dash]S) →π* transition. Although both complexes show subtle differences in behaviour, their spectral changes are distinct, and the origin of changes in their absorption spectra upon oxidation and reduction is successfully interpreted.
这项工作结合了紫外-可见光谱电化学实验和使用 Gaussian 09 程序的理论计算,对两个钌多吡啶配合物在单电子氧化还原过程中吸收光谱变化的起源进行了解释。我们制备了一种含有 p-溴苯甲酰基硫脲单元连接到 1,10-菲咯啉(phen-p-BrBT)的双螯合配体。phen-p-BrBT 与钌双二亚胺中心配位,生成八面体 Ru(ii)三二亚胺配合物,然后对其进行合成和结构表征。这两个配合物表现出相似的 MLCT 带和电子能级,这归因于 bpy 和 phen 配体具有相似的电子结构。然而,由于 phen 二亚胺配体的π电子系统略微更分散,[Ru(phen)(phen-p-BrBT)] 表现出稍宽的可见区 MLCT(金属到配体电荷转移)带,而[Ru(bpy)(phen-p-BrBT)] 则没有。此外,由于 bpy HOMO 比 phen 的 HOMO 更稳定,因此相对于[Ru(bpy)(phen-p-BrBT)],[Ru(phen)(phen-p-BrBT)] 的 UV 中的π→π吸收蓝移。phen 中的额外 C-C 键导致电子密度的更大离域,从而导致π→π跃迁的蓝移。由于一个电子的去除稳定了 Ru d 轨道,因此 MLCT 带在氧化时蓝移并强度降低。还原时,在 UV 区出现一个新的宽吸收带。新的跃迁归因于[Ru(bpy)(phen-p-BrBT)]的第一个 MLCT 跃迁的蓝移和[Ru(phen)(phen-p-BrBT)]的第二个 MLCT 跃迁的红移。新的跃迁起源于配体 LUMO 轨道相对于 Ru d 轨道的失稳或稳定。初始配合物中 UV 带的红移也有助于还原[Ru(bpy)(phen-p-BrBT)]产生的新带。新带不涉及 n(C[双键,长度为 m-dash]S)→π*跃迁。尽管两个配合物的行为都有细微的差异,但它们的光谱变化是明显的,并且成功解释了它们在氧化还原过程中吸收光谱变化的原因。
