Senegas Jean-Michel, Bernardinelli Gérald, Imbert Daniel, Bünzli Jean-Claude G, Morgantini Pierre-Yves, Weber Jacques, Piguet Claude
Department of Inorganic, Analytical and Applied Chemistry, University of Geneva, 30 quai E. Ansermet, CH-1211 Geneva 4, Switzerland.
Inorg Chem. 2003 Jul 28;42(15):4680-95. doi: 10.1021/ic034231t.
The hydrolysis of terminal (t)butyl-ester groups provides the novel nonadentate podand tris[2-[N-methylcarbamoyl-(6-carboxypyridine-2)-ethyl]amine] (L13) which exists as a mixture of slowly interconverting conformers in solution. At pH = 8.0 in water, its deprotonated form L13 - 3H reacts with Ln(ClO(4))(3) to give the poorly soluble and stable podates [Ln(L13 - 3H)] (log(beta(110)) = 6.7-7.0, Ln = La-Lu). The isolated complexes Ln(L13 - 3H)(7) (Ln = Eu, 8; Tb, 9; Lu, 10) are isostructural, and their crystal structures show Ln(III) to be nine-coordinate in a pseudotricapped trigonal prismatic site defined by the donor atoms of the three helically wrapped tridentate binding units of L13. The Ln-O(carboxamide) bonds are only marginally longer than the Ln-O(carboxylate) bonds in [Ln(L13 - 3H)], thus producing a regular triple helix around Ln(III) which reverses its screw direction within the covalent Me-TREN tripod. High-resolution emission spectroscopy demonstrates that (i) the replacement of terminal carboxamides with carboxylates induces only minor electronic changes for the metallic site, (ii) the solid-state structure is maintained in water, and (iii) the metal in the podate is efficiently protected from interactions with solvent molecules. The absolute quantum yields obtained for [Eu(L13 - 3H)] (Phi(Eu)(tot)= 1.8 x 10(-3)) and [Tb(L13 - 3H)] (Phi(Eu)(tot)= 8.9 x 10(-3)) in water remain modest and strongly contrast with that obtained for the lanthanide luminescence step (Phi(Eu) = 0.28). Detailed photophysical studies assign this discrepancy to the small energy gap between the ligand-centered singlet ((1)pi pi*) and triplet ((3)pi pi*) states which limits the efficiency of the intersystem crossing process. Theoretical TDDFT calculations suggest that the connection of a carboxylate group to the central pyridine ring prevents the sizable stabilization of the triplet state required for an efficient sensitization process. The thermodynamic and electronic origins of the advantages (stability, lanthanide quantum yield) and drawbacks (solubility, sensitization) brought by the "carboxylate effect" in lanthanide complexes are evaluated for programming predetermined properties in functional devices.
末端叔丁酯基团的水解产生了新型九齿开链配体三2-[N-甲基氨基甲酰基-(6-羧基吡啶-2)-乙基]胺,它在溶液中以缓慢相互转化的构象异构体混合物形式存在。在水中pH = 8.0时,其去质子化形式L13 - 3H与Ln(ClO4)3反应生成难溶且稳定的多齿配合物[Ln(L13 - 3H)] (log(β110) = 6.7 - 7.0,Ln = La - Lu)。分离得到的配合物Ln(L13 - 3H)7 (Ln = Eu, 8; Tb, 9; Lu, 10)是同构的,其晶体结构表明Ln(III)在由L13的三个螺旋缠绕的三齿配位单元的供体原子定义的伪三帽三棱柱位点中为九配位。Ln - O(甲酰胺)键仅比[Ln(L13 - 3H)]中的Ln - O(羧酸盐)键略长,从而在Ln(III)周围形成规则的三螺旋,该三螺旋在共价Me - TREN三脚架内反转其螺旋方向。高分辨率发射光谱表明:(i)用羧酸盐取代末端甲酰胺仅引起金属位点的微小电子变化;(ii)固态结构在水中得以保持;(iii)多齿配合物中的金属有效地免受与溶剂分子相互作用的影响。在水中[Eu(L13 - 3H)] (ΦEu(tot)= 1.8×10-3)和[Tb(L13 - 3H)] (ΦEu(tot)= 8.9×10-3)获得的绝对量子产率仍然适中,与镧系元素发光步骤获得的量子产率(ΦEu = 0.28)形成强烈对比。详细的光物理研究将这种差异归因于以配体为中心的单重态((1)ππ*)和三重态((3)ππ*)之间的小能隙,这限制了系间窜越过程的效率。理论TDDFT计算表明,羧酸盐基团与中心吡啶环的连接阻止了有效敏化过程所需的三重态的显著稳定化。针对在功能器件中编程预定特性,评估了镧系元素配合物中“羧酸盐效应”带来的优势(稳定性、镧系元素量子产率)和劣势(溶解性、敏化)的热力学和电子学起源。
