Quantum dots: Another choice to sensitize organic transformations

IF 6.1 Q2 CHEMISTRY, PHYSICAL Chemical physics reviews Pub Date : 2023-03-01 DOI:10.1063/5.0126893
Chen Ye, Deqi Zhang, Bin Chen, C. Tung, Lizhu Wu
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Abstract

Photochemical reactions are among the most important reactions in both theoretical studies and practical applications, since they utilize photon energy as the primary driving force. The sensitizer species is the key component connecting photons and the chemical materials of the reaction, which is conventionally among organic dyes or metal complex molecules. Semiconductor quantum dots (QDs), widely used in optoelectronic materials, and fluorescence sensing can be also applied to organic transformations due to their inherent physical and chemical properties. The similar functionalities and special photophysical features make QDs an ideal sensitizer and promote the efficient progress of the photochemical reactions. Moreover, the booming of QD photocatalysis reveals the excellent potential of interdisciplinary development between nano-materials science and organic chemistry QDs. Hence, a systematical explanation of the reaction principle of QDs in photocatalytic processes is necessary. In this review, we analyze the structural and optical properties of the QDs and illustrate how QDs participate in and facilitate organic reactions belonging to different pathways. We also present an outlook on the development of QD photocatalysis.
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量子点:敏化有机转化的另一选择
光化学反应是理论研究和实际应用中最重要的反应之一,因为它们利用光子能量作为主要驱动力。敏化剂是连接光子和反应的化学材料的关键成分,通常在有机染料或金属络合物分子中。半导体量子点(QDs)广泛应用于光电子材料中,由于其固有的物理和化学性质,荧光传感也可应用于有机转化。类似的功能和特殊的光物理特性使量子点成为理想的敏化剂,并促进光化学反应的有效进行。此外,量子点光催化的蓬勃发展揭示了纳米材料科学与有机化学量子点之间跨学科发展的巨大潜力。因此,有必要系统地解释量子点在光催化过程中的反应原理。在这篇综述中,我们分析了量子点的结构和光学性质,并说明了量子点如何参与和促进属于不同途径的有机反应。并对QD光催化技术的发展进行了展望。
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