The synthesis and application of crystalline–amorphous hybrid materials
Literature Information
Publication Date
2023-12-20
DOI
10.1039/D3CS00860F
Impact Factor
54.564
Authors
Hao Lan, Jiawei Wang, Liwei Cheng, Dandan Yu, Hua Wang, Lin Guo
View Original
Abstract
Crystalline–amorphous hybrid materials (CA-HMs) possess the merits of both pure crystalline and amorphous phases. Abundant dangling bonds, unsaturated coordination atoms, and isotropic structural features in the amorphous phase, as well as relatively high electronic conductivity and thermodynamic structural stability of the crystalline phase simultaneously take effect in CA-HMs. Furthermore, the atomic and bandgap mismatch at the CA-HM interface can introduce more defects as extra active sites, reservoirs for promoted catalytic and electrochemical performance, and induce built-in electric field for facile charge carrier transport. Motivated by these intriguing features, herein, we provide a comprehensive overview of CA-HMs on various aspects—from synthetic methods to multiple applications. Typical characteristics of CA-HMs are discussed at the beginning, followed by representative synthetic strategies of CA-HMs, including hydrothermal/solvothermal methods, deposition techniques, thermal adjustment, and templating methods. Diverse applications of CA-HMs, such as electrocatalysis, batteries, supercapacitors, mechanics, optoelectronics, and thermoelectrics along with underlying structure–property mechanisms are carefully elucidated. Finally, challenges and perspectives of CA-HMs are proposed with an aim to provide insights into the future development of CA-HMs.
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Source Journal
Chemical Society Reviews
CiteScore:
80.8
Self-citation Rate:
1.2%
Articles per Year:
250
Chem Soc Rev publishes review articles covering important topics at the forefront of the chemical sciences. Reviews should be of the very highest quality and international impact. We particularly encourage international and multidisciplinary collaborations among our authors. Our scope covers the breadth of the chemical sciences, including interdisciplinary topics where the article has a basis in chemistry. Topics include: Analytical chemistry Biomaterials chemistry Bioorganic/medicinal chemistry Catalysis Chemical Biology Coordination Chemistry Crystal Engineering Energy Sustainable chemistry Green chemistry Inorganic chemistry Inorganic materials Main group chemistry Nanoscience Organic chemistry Organic materials Organometallics Physical chemistry Supramolecular chemistry Synthetic methodology Theoretical and computational chemistry
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CAS Number:
12150-46-8
Molecular Formula:
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