Xingtang Xu , Jie Feng , Wen-Ying Li , Guojie Wang , Wei Feng , Haifeng Yu
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引用次数: 0
Abstract
Molecular solar thermal (MOST) fuels have attracted enormous research enthusiasm in solar energy conversion and storage, which can generate high-energy isomers upon harvesting photon energy and release heat on demand through reversible isomerization of molecular photo-switches such as azobenzene. However, the pristine azobenzene suffers from limitations like low energy density, short half-life and narrow absorption waveband. Recently, numerous azobenzene-based MOST fuels have been developed by various strategies including molecular engineering and template self-assembly to enhance the storage capacities, among which azobenzene-containing polymers (i.e., ‘azopolymers’) are the most promising materials for the development of MOST fuels. In this review, the state-of-the-art advances in azopolymer MOST fuels are systematically summarized. The critical parameters of azobenzene-based MOST fuels are highlighted. Various kinds of azopolymers for solar thermal energy storage and release such as azobenzene compound/polymer composites, linear azopolymers, dendrimer azopolymers, and other types of azopolymers are addressed. The most promising advantages and challenges of azopolymers for MOST fuels are analyzed, and emerging strategies as well as opportunities for future development are discussed with the goal to promote future development of MOST fuels towards innovative applications.
分子太阳能热(MOST)燃料在太阳能转换和储存领域吸引了巨大的研究热情,它可以通过分子光开关(如偶氮苯)的可逆异构化,在收集光子能量时产生高能异构体,并按需释放热量。然而,原始偶氮苯存在能量密度低、半衰期短、吸收波段窄等局限性。最近,人们通过分子工程和模板自组装等各种策略开发出了许多以偶氮苯为基础的 MOST 燃料,以提高其储存能力,其中含偶氮苯的聚合物(即 "偶氮聚合物")是最有希望开发 MOST 燃料的材料。本综述系统地总结了偶氮聚合物 MOST 燃料的最新进展。重点介绍了偶氮苯基 MOST 燃料的关键参数。还讨论了用于太阳能热能储存和释放的各种偶氮聚合物,如偶氮苯化合物/聚合物复合材料、线性偶氮聚合物、树枝状偶氮聚合物和其他类型的偶氮聚合物。分析了用于 MOST 燃料的偶氮聚合物最有前景的优势和挑战,讨论了未来发展的新兴战略和机遇,旨在促进 MOST 燃料未来向创新应用发展。
期刊介绍:
Progress in Polymer Science is a journal that publishes state-of-the-art overview articles in the field of polymer science and engineering. These articles are written by internationally recognized authorities in the discipline, making it a valuable resource for staying up-to-date with the latest developments in this rapidly growing field.
The journal serves as a link between original articles, innovations published in patents, and the most current knowledge of technology. It covers a wide range of topics within the traditional fields of polymer science, including chemistry, physics, and engineering involving polymers. Additionally, it explores interdisciplinary developing fields such as functional and specialty polymers, biomaterials, polymers in drug delivery, polymers in electronic applications, composites, conducting polymers, liquid crystalline materials, and the interphases between polymers and ceramics. The journal also highlights new fabrication techniques that are making significant contributions to the field.
The subject areas covered by Progress in Polymer Science include biomaterials, materials chemistry, organic chemistry, polymers and plastics, surfaces, coatings and films, and nanotechnology. The journal is indexed and abstracted in various databases, including Materials Science Citation Index, Chemical Abstracts, Engineering Index, Current Contents, FIZ Karlsruhe, Scopus, and INSPEC.
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