Ross Daniel A W, Findlay James A, Vasdev Roan A S, Crowley James D
Department of Chemistry, University of Otago, P.O. Box 56, Dunedin 9054, New Zealand.
MacDiarmid Institute for Advanced Materials and Nanotechnology, Wellington 6140, New Zealand.
ACS Omega. 2021 Oct 27;6(44):30115-30129. doi: 10.1021/acsomega.1c04977. eCollection 2021 Nov 9.
Molecular switching processes are important in a range of areas including the development of molecular machines. While there are numerous organic switching systems available, there are far less examples that exploit inorganic materials. The most common inorganic switching system remains the copper(I)/copper(II) switch developed by Sauvage and co-workers over 20 years ago. Herein, we examine if bidentate 2-(1-benzyl-1-1,2,3-triazol-4-yl)pyridine (pytri) and tridentate 2,6-bis[(4-phenyl-1-1,2,3-triazol-1-yl)methyl]pyridine (tripy) moieties can be used to replace the more commonly exploited polypyridyl ligands 2,2'-bypyridine (bpy)/1,10-phenanthroline (phen) and 2,2';6',2″-terpyridine (terpy) in a copper(I)/(II) switching system. Two new ditopic ligands that feature bidentate (pytri, or bpytri, ) and tridentate tripy metal binding pockets were synthesized and used to generate a family of heteroleptic copper(I) and copper(II) 6,6'-dimesityl-2,2'-bipyridine (diMesbpy) complexes. Additionally, we synthesized a series of model copper(I) and copper(II) diMesbpy complexes. A combination of techniques including nuclear magnetic resonance (NMR) and UV-vis spectroscopies, high-resolution electrospray ionization mass spectrometry, and X-ray crystallography was used to examine the behavior of the compounds. It was found that and formed [(diMesbpy)Cu( or )] complexes where the copper(II) diMesbpy unit was coordinated exclusively in the tridenate tripy binding site. However, when the ligands ( and ) were complexed with copper(I) diMesbpy units, a complex mixture was obtained. NMR and MS data indicated that a 1:1 stoichiometry of [Cu(diMesbpy)] and either or generated three complexes in solution, the dimetallic [(diMesbpy)Cu( or )] and the monometallic [(diMesbpy)Cu( or )] isomers where the [Cu(diMesbpy)] unit is coordinated to either the bidentate or tridentate tripy binding sites of the ditopic ligands. The dimetallic (diMesbpy)Cu( or ) complexes were structurally characterized using X-ray crystallography. Both complexes feature a [Cu(diMesbpy)] coordinated to the bidentate (pytri or bpytri) pocket of the ditopic ligands ( or ), as expected. They also feature a second [Cu(diMesbpy)] coordinated to the nominally tridentate tripy binding site in a four-coordinate hypodentate κ-fashion. Competition experiments with model complexes showed that the binding strength of the bidentate pytri is similar to that of the κ-tripy ligand, leading to the lack of selectivity. The results suggest that the pytri/tripy and bpytri/tripy ligand pairs cannot be used as replacements for the more common bpy/phen-terpy partners due to the lack of selectivity in the copper(I) state.
分子开关过程在包括分子机器开发在内的一系列领域中都很重要。虽然有许多可用的有机开关系统,但利用无机材料的例子要少得多。最常见的无机开关系统仍然是20多年前由索瓦热及其同事开发的铜(I)/铜(II)开关。在此,我们研究双齿2-(1-苄基-1H-1,2,3-三唑-4-基)吡啶(pytri)和三齿2,6-双[(4-苯基-1H-1,2,3-三唑-1-基)甲基]吡啶(tripy)部分是否可用于在铜(I)/(II)开关系统中替代更常用的多吡啶配体2,2'-联吡啶(bpy)/1,10-菲咯啉(phen)和2,2';6',2″-三联吡啶(terpy)。合成了两种具有双齿(pytri,或bpytri,)和三齿tripy金属结合口袋的新型双齿配体,并用于生成一系列杂配铜(I)和铜(II)6,6'-二甲基-2,2'-联吡啶(diMesbpy)配合物。此外,我们合成了一系列模型铜(I)和铜(II)diMesbpy配合物。使用包括核磁共振(NMR)和紫外可见光谱、高分辨率电喷雾电离质谱和X射线晶体学在内的多种技术组合来研究这些化合物的行为。发现 和 形成了[(diMesbpy)Cu(或 )]配合物,其中铜(II)diMesbpy单元仅在三齿tripy结合位点配位。然而,当配体( 和 )与铜(I)diMesbpy单元络合时,得到了复杂的混合物。NMR和MS数据表明,[Cu(diMesbpy)]与 或 的1:1化学计量比在溶液中生成了三种配合物,双金属[(diMesbpy)Cu(或 )]和单金属[(diMesbpy)Cu(或 )]异构体,其中[Cu(diMesbpy)]单元与双齿配体的双齿或三齿tripy结合位点配位。使用X射线晶体学对双金属(diMesbpy)Cu(或 )配合物进行了结构表征。正如预期的那样,两种配合物都具有一个[Cu(diMesbpy)]与双齿配体( 或 )的双齿(pytri或bpytri)口袋配位。它们还具有第二个[Cu(diMesbpy)]以四配位低配位κ-方式与名义上的三齿tripy结合位点配位。与模型配合物的竞争实验表明,双齿pytri的结合强度与κ-tripy配体相似,导致缺乏选择性。结果表明,由于在铜(I)状态下缺乏选择性,pytri/tripy和bpytri/tripy配体对不能用作更常见的bpy/phen-terpy配体的替代品。
