| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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| Research & Development of the Field of Ecological Environment Functional Material and Its Discipline Prospect |
| SUN Jianfeng1,2, Zhang Hong1,2, LIANG Jinsheng1,2,*, WANG Fei1,2, DUAN Xinhui1,2, WANG Yaping1,2
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1 MOE Key Laboratory of Special Functional Materials for Ecological Environment and Information, Hebei University of Technology, Tianjin 300130, China
2 Institute of Power Source and Ecomaterials Science, Hebei University of Technology, Tianjin 300130, China |
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Abstract Lack of resources, shortage of energy and environmental degradation have become three essential problems faced by the sustainable deve-lopment of today's society. As the forerunner and foundation of social progress, traditional materials have brought great material wealth to mankind. Meanwhile, it has also caused the problems of excessive consumption of energy and resource as well as surge in environmental load during the material manufacturing, use and waste. As people's awareness of environmental protection, fitness, and public health security markedly enhances, ecological environment functional material, with a composite of design philosophy “material-environment-ecology-health”, has been paid wide attention by academic, industrial, and educational personnels, and therefore it has been gradually considered as the new growth point of the development of material science and engineering discipline, and its related strategic emerging industry. The research and design of ecological environment functional material not only follows the principle of life cycle assessment but also, by advocating the green material technology, it endows functional materials with the characteristics such as excellent environmental coordination, preferable environmental purification and environmental restoration, and promoting good health. Non-metallic minerals not only have a great variety, abundant reserves and low price, but also have the best compatibility with the natural environment, which gives them a natural advantage in the process of preparing ecological environment functional materials. At present, the ecological environment functional material developed with natural mineral resource as the main raw material has exhibited great practical potential in environmental pollution prevention and microenvironmental regulation. This review introduced the connotation and conception as well as the recent development of ecological environment functional material, and further presented the recent advances and development trends of the typical ecological environment functional materials such as sepiolite, montmorillonite, tourmaline, diatomite, biochar, and iron ore tailing. In order to provide reference for the future development of ecological environment functional materials industry and corresponding innovating personnel training mode, this review finally summarized the development trend of the study on ecological environment functional material and the related industry.
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Published: 14 July 2021
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| Fund:This work was financially supported by the Gaint Plan of Hebei Province——Innovation Team Leader Talent Plan (2018). |
About author:: Jianfeng Sun received his B.S. Degree in environmental engineering from Beijing Technology and Business University in 2005, and received his Ph.D degree in chemistry from Tsinghua University in 2014 under the supervision of Prof. Dezhong Shen, academician of the Chinese Academy of Engineering. His doctor’s thesis mainly focused on the study of novel nonlinear optical crystals. From 2014, he has been working as an associate professor at Hebei University of Technology. He is the young editor of Journal of Synthetic Crystals and Chinese Journal of Luminescence. His current research interest focuses on designing novel rare earth phosphors for solid-state lighting, including the structural discovery and structure-property relation studies.
Jinsheng Liang researcher, doctoral supervisor. He is the director of Key Laboratory of Ministry of Education of Eco-environment and Information Special Functional Materials. He has long been engaged in research work on functional materials for ecological environment. He has systematically studied the theory and technology of energy-saving and environmental protection functiona-lization of non-metallic mineral materials. He has successfully developed advanced preparation technology of high-performance tourmaline and sepiolite mineral materials and its application technology in combustion, energy-saving, environmental protection, functional ceramics and other fields. Hosted a total of 3 key projects of the National 863 Program and the National Science and Technology Support Program during the 10th Five-Year Plan, the 11th Five-Year Plan and the 12th Five-Year Plan period. Now he is the project manager of the 13th Five-Year National Key R&D Program “Environmental Non-metallic Mineral Functional Materials Preparation Technology and Application Research”. |
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2021, Vol. 35 
