Practical applications of total internal reflection fluorescence microscopy for nanocatalysis

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摘要 Fluorescence microscopy has evolved from a purely biological tool to a powerful chemical instrument for imaging and kinetics research into nanocatalysis.And the demand for high signal-to-noise ratio and temporal–spatial resolution detection has encouraged rapid growth in total internal reflection fluorescence microscopy(TIRFM).By producing an evanescent wave on the glass–water interface,excitation can be limited to a thin plane to ensure the measured accuracy of kinetics and image contrast of TIRFM.Thus,this unique physical principle of TIRFM makes it suitable for chemical research.This review outlines applications of TIRFM in the field of chemistry,including imaging and kinetics research.Hence,this review could provide guidance for beginners employing TIRFM to solve current challenges creatively in chemistry.

作者 Chengyang Yan Xuanhao Mei Xue Gong Weilin Xu

机构地区 State Key Laboratory of Electroanalytical Chemistry University of Science and Technology of China

出处《Industrial Chemistry & Materials》 2024年第1期85-99,共15页 工业化学与材料（英文）

基金 This work was supported by the National Science Foundation of China(21925205,22072145,22102172,21721003)。

关键词 Total internal reflection fluorescence microscopy NANOCATALYSIS IMAGING Kinetics analysis

分类号 O64 [理学—物理化学]

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1Dong Su.Advanced electron microscopy characterization of nanomaterials for catalysis[J].Green Energy & Environment,2017,2(2):70-83. 被引量：3
2Alan J. McCue,James A. Anderson.ecent advances in selective acetylene hydrogenation using palladium containing catalysts[J].Frontiers of Chemical Science and Engineering,2015,9(2):142-153. 被引量：21
3Yanshu Zhang,Gongke Li,Yufei Hu.Fabrication of bimetallic nanoparticles modified hollow nanoporous carbons derived from covalent organic framework for efficient degradation of 2,4-dichlorophenol[J].Chinese Chemical Letters,2021,32(8):2529-2533. 被引量：1

二级参考文献67

1Tiedtke D B, Cheung T T P, Leger J, Zisman S A, Bergmeister J J, Delzer G A. In: 13th Ethylene Producers Conference, 2001, 10: 1-21.
2Borodzinski A, Bond G C. Selective Hydrogenation of ethyne in ethene—rich streams on palladium catalysts. Part 1. Effect of changes to the catalyst during reaction. Catalysis Reviews, 2006,48 (2): 91-144.
3Borodzinski A, Bond G C. Selective hydrogenation of ethyne in ethene—rich streams on palladium catalysts. Part 2: Steady—state kinetics and effects of palladium particle size, carbon monoxide, and promoters. Catalysis Reviews, 2008, 50(3): 379^169.
4Nikolaev S A, Zanaveskin I L N, Smirnov V V, Averyanov V A, Zanaveskin K I. Catalytic hydrogenation of alkyne and alkadiene impurities from alkenes. Practical and theoretical aspects. RussianChemical Reviews, 2009, 78(3): 231-247.
5"Garcia-Mota M, Gomez-Diaz J, Novell-Leruth G, Vargas-FuentesC, Bellarosa L, Bridier B, Perez-Ramirez J, Lopez N. A density functional theory study of the “mythic” Lindlar hydrogenation catalyst. Theoretical Chemistry Accounts, 2011, 128(4): 663-673".
6Bridier B, Lopez N, Perez-Ramirez J. Molecular understanding of alkyne hydrogenation for the design of selective catalysts. Dalton Transactions, 2010, 39(36): 8412-8419.
7Segura Y, Lopez N, Perez-Ramirez J. Origin of the superior hydrogenation selectivity of gold nanoparticles in alkyne + alkene mixtures: Triple- versus double-bond activation. Journal of Catalysis, 2007, 247(2): 383-386.
8Vile G, Baudouin D, Remediakis I N, Coperet C, Lopez N, Perez-Ramirez J. Silver nanoparticles for olefin production: New insights into the mechanistic description of propyne hydrogenation. ChemCatChem, 2013, 5(12): 3750-3759.
9Wehrli J T, Thomas D J, Wainwright M S, Trimm D L, Cant N W. Selective hydrogenation of propyne over supported copper catalysts: Influence of support. Applied Catalysis, 1991, 70(1): 253-262.
10Bridier B, Lopez N, Perez-Ramirez J. Partial hydrogenation of propyne over copper-based catalysts and comparison with nickel-based analogues. Journal of Catalysis, 2010, 269(1): 80-92.

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1Lei Zhang,Jin Lin,Zhenpeng Liu,Jian Zhang.Non-noble metal-based catalysts for acetylene semihydrogenation:from thermocatalysis to sustainable catalysis[J].Science China Chemistry,2023,66(7):1963-1974.
2Xiaowen Zhu,Yaodong Huang,Jing-Kang Wang.Steps of fronts in chemical engineering:An overview of the publications of FCSE[J].Frontiers of Chemical Science and Engineering,2018,12(4):593-597.
350 ppm of Pd dispersed on Ni（OH）2 nanosheets catalyzing semi-hydrogenation of acetylene with high activity and selectivity[J].Nano Research,2018,11(2):905-912. 被引量：7
4梁玉龙,张忠宝,李保江,赵玉龙,刘晓旭,王书峰.国产PEC-21前加氢催化剂在大庆石化的工业应用[J].石油化工,2018,47(2):192-196. 被引量：4
5李雨柔,葛小虎,曹约强,段学志,周兴贵,袁渭康.乙炔选择性加氢:催化剂结构敏感性分析及调控[J].化工进展,2020,39(12):4845-4855. 被引量：1
6贡洁,陈文轩,邹宇洲,谢瑜,刘慧楠,童霏.ZIF-67/PVDF杂化膜的制备及其提取钯的性能研究[J].贵金属,2020,41(4):21-26. 被引量：1
7Yueqiang Cao,Xiaohu Ge,Yurou Li,Rui Si,Zhijun Sui,Jinghong Zhou,Xuezhi Duan,Xinggui Zhou.Structural and Kinetics Understanding of Support Effects in Pd-Catalyzed Semi-Hydrogenation of Acetylene[J].Engineering,2021,7(1):103-110. 被引量：1
8童霏,施国栋,陈文轩,贡洁,张怡妮.原位生长法制备沸石咪唑酯骨架结构材料/聚偏氟乙烯杂化膜及其截取钯性能研究[J].化学世界,2021,62(7):400-404.
9Mohamed T.El-Saadony,El-Sayed M.Desoky,Ahmed M.Saad,Rania S.M.Eid,Eman Selem,Ahmed S.Elrys.Biological silicon nanoparticles improve Phaseolus vulgaris L. yield and minimize its contaminant contents on a heavy metals-contaminated saline soil[J].Journal of Environmental Sciences,2021,33(8):1-14. 被引量：3
10Lei Wang,Peng Yin,Wei-Jie Zeng,Shi-Long Xu,Ping Chen,Hai-Wei Liang.Bulky nanodiamond-confined synthesis of sub-5 nanometer ordered intermetallic Pd_(3)Pb catalysts[J].Nano Research,2022,15(6):4973-4979. 被引量：3

1Haixiang Huang,Tingting Xu,Jinting Chen,Yang Zhao,ujie Lv,Bogu Liu,Bao Zhang,Jianguang Yuan,Ying Wu.Efficient nanocatalysis of Ni/Sc_(2)O_(3)@FLG for magnesium hydrolysis of hydrogen generation[J].Journal of Materials Science & Technology,2024,175(8):235-243.
2Ke Cao,Yan Zhou,Shanshan Lv,Mengmeng Feng,Changjin Qian,Zheng Chen.Cobalt-manganese bimetallic organic frameworks catalyzed solvent-free oxidation of benzyl C-H bonds with O_(2) as sole oxidant[J].Nano Research,2024,17(11):9532-9539.
3Fei-Teng Wang,Xiandong Liu,Jun Cheng.Water structures and anisotropic dynamics at Pt(211)/water interface revealed by machine learning molecular dynamics[J].Materials Futures,2024,3(4):1-10.
4Jinli Han,Ting Zhang,Xiaochun Zhou.Driving Forces for Single DNA Stretching Assessed by In Situ TIRFM[J].Chemical & Biomedical Imaging,2023,1(2):140-146.
5Chongqing Kang,Ziyang Zhang,Hongyi Wei,Ershun Du,Peng Wang,Ning Zhang.Power system decarbonization pathway of China[J].iEnergy,2024,3(1):7-11.
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9Ram B.Misra,Yang Li.A Constructive Use of ChatGPT in the Classroom:An Empirical Study[J].Journal of Artificial Intelligence and Technology,2024,4(4):318-324.
10Xuyang Chang,Rifa Zhao,Shaowei Jiang,Cheng Shen,Guoan Zheng,Changhuei Yang,Liheng Bian.Complex-domain-enhancing neural network for large-scale coherent imaging[J].Advanced Photonics Nexus,2023,2(4):79-87.

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Practical applications of total internal reflection fluorescence microscopy for nanocatalysis

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