Precise Synthesis at the Atomic Scale

Precise synthesis at the atomic scale is a highly desirable and controllable route for the preparation of heterogeneous catalysts with the desired structure and properties, which promotes the rational design of highly efficient catalysts and facilitates the understanding of structure-properties rela...

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Published inPrecision Chemistry Vol. 1; no. 4; pp. 199 - 225
Main Authors Ji, Shufang, Jun, Caroline, Chen, Yuanjun, Wang, Dingsheng
Format Journal Article
LanguageEnglish
Published University of Science and Technology of China and American Chemical Society 26.06.2023
American Chemical Society
Subjects
Review
active sites
heterogeneous catalysts
catalysis
atomic scale
Precise synthesis
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Abstract Precise synthesis at the atomic scale is a highly desirable and controllable route for the preparation of heterogeneous catalysts with the desired structure and properties, which promotes the rational design of highly efficient catalysts and facilitates the understanding of structure-properties relationship. The precise construction of the active sites of the catalysts provides important opportunities for atomic insight into the correlation between structure and catalytic performance. In this review, the atomic-level tuning strategies for the precise synthesis of heterogeneous catalysts are summarized with the emphasis on the precise control of the structure of active sites, including single atom sites, dual atom sites and complex active sites. Furthermore, we illustrate the crucial role of atomic-level regulation of structure in determining the catalytic performance by providing typical catalysis examples in different reactions. In the end, some perspectives on the further development of precise synthesis of catalysts at the atomic level are presented.
AbstractList Precise synthesis at the atomic scale is a highly desirable and controllable route for the preparation of heterogeneous catalysts with the desired structure and properties, which promotes the rational design of highly efficient catalysts and facilitates the understanding of structure-properties relationship. The precise construction of the active sites of the catalysts provides important opportunities for atomic insight into the correlation between structure and catalytic performance. In this review, the atomic-level tuning strategies for the precise synthesis of heterogeneous catalysts are summarized with the emphasis on the precise control of the structure of active sites, including single atom sites, dual atom sites and complex active sites. Furthermore, we illustrate the crucial role of atomic-level regulation of structure in determining the catalytic performance by providing typical catalysis examples in different reactions. In the end, some perspectives on the further development of precise synthesis of catalysts at the atomic level are presented.
Precise synthesis at the atomic scale is a highly desirable and controllable route for the preparation of heterogeneous catalysts with the desired structure and properties, which promotes the rational design of highly efficient catalysts and facilitates the understanding of structure-properties relationship. The precise construction of the active sites of the catalysts provides important opportunities for atomic insight into the correlation between structure and catalytic performance. In this review, the atomic-level tuning strategies for the precise synthesis of heterogeneous catalysts are summarized with the emphasis on the precise control of the structure of active sites, including single atom sites, dual atom sites and complex active sites. Furthermore, we illustrate the crucial role of atomic-level regulation of structure in determining the catalytic performance by providing typical catalysis examples in different reactions. In the end, some perspectives on the further development of precise synthesis of catalysts at the atomic level are presented.
Author Ji, Shufang
Wang, Dingsheng
Jun, Caroline
Chen, Yuanjun
AuthorAffiliation Department of Chemistry
Department of Electrical and Computer Engineering
AuthorAffiliation_xml – name: Department of Electrical and Computer Engineering
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  fullname: Ji, Shufang
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  givenname: Caroline
  surname: Jun
  fullname: Jun, Caroline
  organization: Department of Chemistry
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  givenname: Yuanjun
  surname: Chen
  fullname: Chen, Yuanjun
  organization: Department of Electrical and Computer Engineering
– sequence: 4
  givenname: Dingsheng
  orcidid: 0000-0003-0074-7633
  surname: Wang
  fullname: Wang, Dingsheng
  email: wangdingsheng@mail.tsinghua.edu.cn
  organization: Department of Chemistry
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Keywords active sites
heterogeneous catalysts
catalysis
atomic scale
Precise synthesis
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Snippet Precise synthesis at the atomic scale is a highly desirable and controllable route for the preparation of heterogeneous catalysts with the desired structure...
Precise synthesis at the atomic scale is a highly desirable and controllable route for the preparation of heterogeneous catalysts with the desired structure...
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Title Precise Synthesis at the Atomic Scale
URI http://dx.doi.org/10.1021/prechem.3c00022
https://pubmed.ncbi.nlm.nih.gov/PMC12382268
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