Department of Chemistry, University of Sheffield, Sheffield S3 7HF, UK.
Dalton Trans. 2019 May 7;48(18):6132-6152. doi: 10.1039/c9dt00954j.
A ligand skeleton combining a 1,10-phenanthroline (phen) binding site and one or two heptadentate N3O4 aminocarboxylate binding sites, connected via alkyne spacers to the phen C3 or C3/C8 positions, has been used to prepare a range of heteronuclear Ru·M and Ru·M2 complexes which have been evaluated for their cell imaging, relaxivity, and photophysical properties. In all cases the phen unit is bound to a {Ru(bipy)2}2+ unit to give a phosphorescent {Ru(bipy)2(phen)}2+ luminophore, and the pendant aminocarboxylate sites are occupied by a secondary metal ion M which is either a lanthanide [Gd(iii), Nd(iii), Yb(iii)] or another d-block ion [Zn(ii), Mn(ii)]. When M = Gd(iii) or Mn(ii) these ions provide the complexes with a high relaxivity for water; in the case of Ru·Gd and Ru·Gd2 the combination of high water relaxivity and 3MLCT phosphorescence from the Ru(ii) unit provides the possibility of two different types of imaging modality in a single molecular probe. In the case of Ru·Mn and Ru·Mn2 the Ru(ii)-based phosphorescence is substantially reduced compared to the control complexes Ru·Zn and Ru·Zn2 due to the quenching effect of the Mn(ii) centres. Ultrafast transient absorption spectroscopy studies on Ru·Mn (and Ru·Zn as a non-quenched control) reveal the occurrence of fast (<1 ns) PET in Ru·Mn, from the Mn(ii) ion to the Ru(ii)-based 3MLCT state, i.e. MnII-(phen˙-)-RuIII → MnIII-(phen˙-)-RuII; the resulting MnIII-(phen˙-) state decays with τ ≈ 5 ns and is non-luminescent. This occurs in conformers when an ET pathway is facilitated by a planar, conjugated bridging ligand conformation connecting the two units across the alkyne bridge but does not occur in conformers where the two units are electronically decoupled by a twisted conformation of the bridging ligand. Computational studies (DFT) on Ru·Mn confirmed both the occurrence of the PET quenching pathway and its dependence on molecular conformation. In the complexes Ru·Ln and Ru·Ln2 (Ln = Nd, Yb), sensitised near-infrared luminescence from Nd(iii) or Yb(iii) is observed following photoinduced energy-transfer from the Ru(ii) core, with Ru → Nd energy-transfer being faster than Ru → Yb energy-transfer due to the higher density of energy-accepting states on Nd(iii).
一种配体骨架结合了 1,10-菲咯啉(phen)结合位点和一个或两个七齿 N3O4 氨基羧酸酯结合位点,通过炔烃间隔物连接到 phen C3 或 C3/C8 位置,已被用于制备一系列异核 Ru·M 和 Ru·M2 配合物,这些配合物已被评估用于细胞成像、弛豫率和光物理性质。在所有情况下,phen 单元都与 {Ru(bipy)2}2+ 单元结合,得到磷光 {Ru(bipy)2(phen)}2+ 发光体,而悬垂的氨基羧酸酯位点被第二金属离子 M 占据,M 要么是镧系元素 [Gd(iii), Nd(iii), Yb(iii)] 要么是另一个 d 区离子 [Zn(ii), Mn(ii)]。当 M = Gd(iii) 或 Mn(ii) 时,这些离子为配合物提供了对水的高弛豫率;在 Ru·Gd 和 Ru·Gd2 的情况下,Ru(ii)单元的高水弛豫率和 3MLCT 磷光的组合为单个分子探针中的两种不同类型的成像模式提供了可能性。在 Ru·Mn 和 Ru·Mn2 的情况下,与对照配合物 Ru·Zn 和 Ru·Zn2 相比,由于 Mn(ii)中心的猝灭效应,基于 Ru(ii)的磷光显著降低。Ru·Mn(和 Ru·Zn 作为非猝灭对照)的超快瞬态吸收光谱研究表明,在 Ru·Mn 中发生了快速(<1 ns)的 PET,从 Mn(ii)离子到基于 Ru(ii)的 3MLCT 态,即 MnII-(phen˙-)-RuIII → MnIII-(phen˙-)-RuII;由此产生的 MnIII-(phen˙-)态以 τ ≈ 5 ns 衰减且无发光。当 ET 途径通过连接两个单元的平面共轭桥连配体构象得到促进时,在构象中发生这种情况,但在桥连配体的扭曲构象使两个单元电子解耦的构象中不发生这种情况。对 Ru·Mn 的计算研究(DFT)证实了 PET 猝灭途径的发生及其对分子构象的依赖性。在配合物 Ru·Ln 和 Ru·Ln2(Ln = Nd, Yb)中,观察到 Nd(iii)或 Yb(iii)的敏化近红外发光,这是由于 Ru(ii)核的光诱导能量转移所致,由于 Nd(iii)上的能量接受态密度更高,因此 Ru → Nd 能量转移比 Ru → Yb 能量转移更快。
