基于半导体量子点CdSe/ZnS和功能化卟啉配体的纳米复合材料的非fret光致猝灭

E. Zenkevich, T. Blaudeck, A. Milekhin, C. Borczyskowski
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引用次数: 22

摘要

我们回顾了最近的实验工作,利用附着在表面的功能化卟啉分子诱导胶体半导体量子点发光猝灭的尺寸依赖性来描述不同于通常的电荷转移(CT)或福斯特共振能量转移(FRET)模型的光致发光(PL)猝灭过程。在295 K的甲苯中,对基于胶体CdSe/ZnS和不同尺寸的CdSe量子点(QDs)和表面附着四介吡啶取代卟啉分子(“量子点卟啉”纳米复合材料)的纳米复合材料进行了稳态和皮秒时间分辨测量。研究发现,“量子点-卟啉”纳米复合材料中量子点PL的强猝灭主要不是由于FRET引起的,也不是由于量子点与发色团之间的光致电荷转移引起的。这种PL猝灭取决于量子点的大小和壳层,对于较小的量子点更强:量子点PL猝灭速率常数𝑘𝑞与量子点直径成反比。通过对实验数据和量子力学计算的比较,得出“QD-卟啉”纳米复合材料中QD PL的猝灭可以理解为电子(激发态电子-空穴对)的隧穿,然后是电子的(自)局域化或陷阱态的形成。发现对PL猝灭的主要贡献与量子点表面计算的量子限制激子波函数成正比。我们的研究结果表明,单个功能化分子可以被认为是胶体半导体量子点复杂界面物理和动力学的探针之一。
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Size-Dependent Non-FRET Photoluminescence Quenching in Nanocomposites Based on Semiconductor Quantum Dots CdSe/ZnS and Functionalized Porphyrin Ligands
We review recent experimental work to utilize the size dependence of the luminescence quenching of colloidal semiconductor quantum dots induced by functionalized porphyrin molecules attached to the surface to describe a photoluminescence (PL) quenching process which is different from usual models of charge transfer (CT) or Foerster resonant energy transfer (FRET). Steady-state and picosecond time-resolved measurements were carried out for nanocomposites based on colloidal CdSe/ZnS and CdSe quantum dots (QDs) of various sizes and surfacely attached tetra-mesopyridyl-substituted porphyrin molecules (“Quantum Dot-Porphyrin” nanocomposites), in toluene at 295 K. It was found that the major part of the observed strong quenching of QD PL in “QD-Porphyrin” nanocomposites can neither be assigned to FRET nor to photoinduced charge transfer between the QD and the chromophore. This PL quenching depends on QD size and shell and is stronger for smaller quantum dots: QD PL quenching rate constants 𝑘𝑞 scale inversely with the QD diameter. Based on the comparison of experimental data and quantum mechanical calculations, it has been concluded that QD PL quenching in “QD-Porphyrin” nanocomposites can be understood in terms of a tunneling of the electron (of the excited electron-hole pair) followed by a (self-) localization of the electron or formation of trap states. The major contribution to PL quenching is found to be proportional to the calculated quantum-confined exciton wave function at the QD surface. Our findings highlight that single functionalized molecules can be considered as one of the probes for the complex interface physics and dynamics of colloidal semiconductor QD.
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