Materials Reports 2021, Vol. 35 Issue (Z1): 121-127 |
INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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Influence of Metal Organic Framework Materials Synthesis Method on the Adsorption Performance of Nitrogen Oxides |
CUI Xinghui, WU Xiaopeng, QI Wenhao, XING Yiqiang, PAN Mengbo, DU Haoran, MA Chengliang
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Henan Key Laboratory of High Temperature Functional Ceramics,School of Materials Science and Engineering, Zhengzhou University, Zhengzhou 450052, China |
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Abstract Metal organic framework materials have good gas adsorption performance due to their high specific surface area and porosity. Compared with traditional NOx adsorption materials, MOFs have ultra-high specific surface area and porosity, rich and diverse structures and periodicity, and good thermal and chemical stability. The synthesis methods of MOFs have been studied a lot to get a high adsorption efficiency of NOx. The synthesis methods of MOFs mainly include hydrothermal method, solvothermal method, ultrasonic synthesis method and microwave synthesis method. The hydrothermal method has an easy operation and high crystal quality but a large crystal grains and small pore volume; The principles of the solvothermal method and the hydrothermal method are same. By adding organic solvents with different functional groups, the synthesized material can have a richer structure, larger specific surface area, and a better adsorption property on NOx than hydrothermal method. So it is also the most widely used method; the MOFs synthesized by ultrasonic synthesis method has small particle and uniform size,large specific surface area and pore volume, and good NOx adsorption property but high cost; the microwave synthesis method can accelerate the reaction process to get a smaller particle size, specific surface area and pore volume, and a high adsorption capacity for NOx, but it also has the disadvantage of high economic cost. Therefore, we summarize the synthesis methods and modification technologies of MOFs in this article, and analyze the effects of MOFs synthesized by different methods on the adsorption of NOx, and then prospecte the development trend of MOFs for adsorbing NOx.
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Published: 16 July 2021
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Fund:National Natural Science Fountation of China(51872265), the “13th Five-Year”Research and Development Program of China(2017YFB0310701). |
About author:: Xinghui Cui received her B.E. degree in Luoyang Institute of Science and Technology in 2018. She is currently pursuing her master's degree at the School of Materials Science and Engineering,Zhengzhou University under the supervision of associate professor Chengliang Ma.Her research has focused on nitrogen oxide emission reduction technology in high temperature kilns.Chengliang Ma is a professor of Zhengzhou University, a doctoral supervisor, the director of the Institute of High Temperature Materials of Zhengzhou University, and the director of the Henan Provincial Key Laboratory of High Temperature Functional Materials. Received a Ph.D. in Materials Processing from Zhengzhou University in 2006 (supervised by Academician Xiangchong Zhong). From November 2000 to present, he has been working at the School of Materials of Zhengzhou University/Institute of High Temperature Functional Materials of Zhengzhou University,December 2018 to December 2019, as a national public visiting scholar at Wake Forest University, USA. He has published more than 50 papers in domestic and foreign academic journals, published 4 monographs, 10 achievements have been identified as internationally advanced, authorized more than 10 national patents, and presided over 3 national natural science foundation projects. The research direction is mainly high-efficiency energy-saving heat insulation materials, new refractory materials for clean steel smelting ladle, and non-oxide composite materials. Won the first Xiangchong Zhong Youth Science and Technology Award, the National Building Material Industry Technology Innovation Award, the National New Product Award, the Second Prize of Henan Science and Technology Progress Award,the Henan Provincial Department of Education Science and Technology Achievement Award, and was named the first prize of "Zhihui Zhengzhou" in 2018 Approve local talents with outstanding contributions. The paper has won the first prize of the 10th Henan Provincial Outstanding Paper in Natural Science, and the first prize of the Henan Provincial Department of Education. Independently or assist Academician Xiangchong Zhong to supervise dozens of master and doctoral students. |
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