材料科学
光催化
微流控
光子上转换
纳米技术
表面改性
可见光谱
光电子学
化学工程
兴奋剂
生物化学
工程类
催化作用
化学
作者
Younghoon You,Mi‐Jeong Kim,Gwang‐Noh Ahn,Sanghyun Bae,Dowon Kim,Jung‐Kyun Kim,Yong‐Eun Kwon,Jungki Ryu,Jiseok Lee,Dong‐Pyo Kim
标识
DOI:10.1002/admt.202101656
摘要
Abstract Microfluidic systems with large surface‐to‐volume ratios and superior light transmission are used to efficiently transfer mass and convert energy, and to enhance photocatalytic reactions. Utilizing the entire solar spectrum for promoting photocatalytic reactions is highly desirable and near‐infrared (NIR) radiation, in particular, has a high transmission efficiency through common polymers and materials used to construct microfluidic devices. Herein, a reliable microfluidic system using bimodal light‐harvesting technique is reported to improve the photocatalytic efficiency of C(sp3)‐H functionalization reactions using coumarin dye (C153) and lanthanide‐doped upconversion nanocrystals (UCNs). Using two light‐harvesting components (C153 and UCNs) in polycarbosilane polymer matrix, a bimodal light‐harvesting microfluidic reactor is realized in which the inner surface of the microfluidic channel is reliably coated with a transparent composite of C153/UCNs to simultaneously downshift visible light and upconvert NIR light. A double‐stacked microfluidic system that successfully enhanced the photocatalytic conversion efficiency of Rose Bengal‐based aza‐Henry photocatalytic reactions by twofold (≈93% conversion). The study provides a design principle of next‐generation microfluidic reactor for a robust photocatalytic organic synthesis.
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