利用配位化学调控CdSe团簇的表面结构和光学性质
Tuning the Surface Structure and Optical Properties of CdSe Clusters Using Coordination Chemistry.
作者信息
Cossairt Brandi M, Juhas Pavol, Billinge Simon, Owen Jonathan S
机构信息
Department of Chemistry, Columbia University, Havemeyer Hall, MC 3121, 3000 Broadway, New York, NY 10027.
出版信息
J Phys Chem Lett. 2011 Nov;2(4):3075-3080. doi: 10.1021/jz2013769.
Abstract
A series of nonstoichiometric CdSe clusters with lowest energy electronic absorptions between 409 - 420 nm has been prepared from cadmium 1-naphthoate, 2-naphthoate, 4-thiomethyl-1-naphthaote, and 1-naphthalene thiolate complexes and diphenylphosphine selenide (DPPSe). Pair distribution function analysis of X-ray diffraction data, ligand exchange experiments, and NMR molecular weight analyses suggest the nanocrystal core changes minimally among these clusters despite significant changes to their absorption and luminescence spectra. Photoluminescence excitation spectra obtained at 77 K reveal an energy transfer process between the surface-trapped excited state and the naphthalene-containing ligands that leads to ligand phosphorescence. A Dexter energy transfer mechanism is proposed to explain the observation of ligand phosphorescence on excitation of the cluster. These compounds demonstrate that cluster absorption and trap luminescence can be controlled with surface coordination chemistry.
摘要
通过镉的1-萘甲酸酯、2-萘甲酸酯、4-硫代甲基-1-萘甲酸酯、1-萘硫醇络合物与二苯基膦硒化物(DPPSe)制备了一系列最低能量电子吸收在409 - 420 nm之间的非化学计量比CdSe簇。X射线衍射数据的对分布函数分析、配体交换实验和核磁共振分子量分析表明,尽管这些簇的吸收光谱和发光光谱发生了显著变化,但其纳米晶核变化极小。在77 K下获得的光致发光激发光谱揭示了表面捕获的激发态与含萘配体之间的能量转移过程,该过程导致配体磷光。提出了一种德克斯特能量转移机制来解释簇激发时配体磷光的观察结果。这些化合物表明,簇的吸收和陷阱发光可以通过表面配位化学来控制。
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