沈曉駿檢視原始碼討論檢視歷史
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沈曉駿,男,北京林業大學講師。
人物簡歷
教育經歷
2017/09-2020/09,中國科學院化學研究所,物理化學,博士,導師:韓布興院士
2014/09-2017/06,北京林業大學,林產化工,碩士,導師:孫潤倉教授
2010/09-2014/06,浙江農林大學,應用化學,學士
工作經歷
2020/12-2022/10,中國科學院大連化學物理研究所,博士後,合作導師:王峰研究員
2022/11-至今,北京林業大學,材料科學與技術學院,講師
研究方向
科研工作
近年來重點圍繞木質纖維素高值化利用和相關研究,特別是木質素高效清潔分離以及木質素定向催化轉化方面,建立了清潔高效的林木生物質和全組分分離方法,同時發展了木質素優先的生物質精煉體系,提出了木質素官能團定向高值化利用製備精細化學品新策略。主持中國科學院特別研究助理項目1項(60萬)和博士後面上項目1項(8萬)。發表SCI論文49篇,總影響因子531,H指數24,其中第一作者/通訊作者/共同第一作者在Chemical Society Reviews,Green Chemistry,Chemical Science,Bioresource Technology,Carbohydrate Polymer等SCI論文25篇,總影響因子255,其中影響因子大於10的有9篇,其中累計3篇SCI論文入選ESI高被引論文,1篇文章在生物質低共熔預處理生物質領域他引全球排行前五。受邀撰寫生物質轉化英文專著1章,申請中國發明專利6件。多次參加國際學術會議,並做報告3次。
獲獎情況
2021年 中國科學院大連化學物理研究所優秀博士後
2020年 梁希青年論文三等獎
2017年 北京林業大學優秀碩士畢業論文
2016年 北京林業大學國家獎學金
學術兼職
擔任Catalysts和Frontiers in Chemical Engineering期刊編委;Frontiers in Energy Research,Frontiers in Chemistry and Frontiers in Bioengineering and Biotechnology客座編輯,此外還擔任本領域Bioresource Technology,Carbohydrate Polymer,ACS Sustainable Chemistry & Engieering,ChemSusChem等十多種SCI期刊審稿人,
學術成果
1. Shen X. J., Zhang C., Han B., Wang F., (2022). Catalytic self-transfer hydrogenolysis of lignin with endogenous hydrogen: road to the carbon-neutral future. Chemical Society Reviews. 51, 1608-1628. (ESI高被引)
2. Shen X. J., Meng Q. L., Mei Q. Q., Liu H. Z., Yang J, Song J. L., Tan D. X., Chen B. F., Zhang Z.R., Yang G.Y., & Han. B.X. (2019). Selectively catalytic transformation of lignin with guaiacol as the only liquid product. Chemical Science, 2020, 11, 1347-1352.
3. Shen X. J., Meng Q. L., Mei Q. Q., Xiang J. F., Liu H. Z., Han B. X. (2020) The production of 4-ethyltoluene via directional valorization of lignin. Green Chemistry, 2020, 22, 2191-2196.
4. Shen X. J., Wen J. L., Mei Q. Q., Chen X., Sun, D., Yuan T. Q., Sun R. C. (2019). Facile fractionation of lignocelluloses by biomass-derived deep eutectic solvent (DES) pretreatment for cellulose enzymatic hydrolysis and lignin valorization. Green Chemistry, 21(2), 275-283. (ESI高被引,生物質低共熔預處理領域他引在全球排行前五)
5. Shen X. J., Meng Q. L., Dong M. H., Xiang J. F., Li S. P., Liu H. Z., Han B. X. (2019) Low Temperature Reverse Water-Gas-Shift Process and Transformation of Renewable Carbon Resources to Value-added Chemicals at Mild Condition. ChemSusChem, 12, 5149-5156.
6. Shen X. J., Wang B., Huang P. L., Wen J. L., Sun R. C. (2016). Effects of aluminum chloride-catalyzed hydrothermal pretreatment on the structural characteristics of lignin and enzymatic hydrolysis. Bioresource Technology, 206, 57-64.
7. Shen X. J., Wen J. L., Chen T. Y. Wang H. M. Mei Q. Q., Yue F. X., Yuan T. Q., Sun R. C. (2019) Structural and Morphological Transformations of Lignin Macromolecules during Bio-based Deep Eutectic Solvent (DES) Pretreatment. ACS Sustainable Chemistry & Engineering, 8, 2130-2137. (ESI高被引)
8. Shen X. J., Sun R. C. (2021) Recent advances in lignocellulose prior-fractionation for biomaterials, biochemicals, and bioenergy. Carbohydrate Polymers. 261, 117884.
9. Shen X. J., Huang P. L., Wen J. L., Sun R. C. (2017). A facile method for char elimination during base-catalyzed depolymerization and hydrogenolysis of lignin. Fuel Processing Technology. 167, 491-501.
10. Shen X. J., Huang P., Li F. F., Wang X., Yuan T., Sun R. (2019). Compressive Alginate Sponge Derived from Seaweed Biomass Resources for Methylene Blue Removal from Wastewater. Polymers. 11(6), 961.
11. Shen X. J., Wang B., Huang P. L., Wen J. L., Sun R. C. (2016). Understanding the structural changes and depolymerization of Eucalyptus lignin under mild conditions in aqueous AlCl3. Rsc Advances. 6(51), 45315-45325.
12. Shen X. J., Wen J. L., Huang P. L., Zheng K., Wang S. F., Liu Q. Y., Sun R. C. (2017). Efficient and Product-Controlled Depolymerization of Lignin Oriented by Raney Ni Cooperated with CsxH3?xPW12O40. BioEnergy Research. 10(4), 1155-1162.
13. Shen X. J., Huang P. L., Chen J. H., Wu Y. Y., Liu Q. Y., Sun R. C. (2017). Comparison of Acid-hydrolyzed and TEMPO-oxidized Nanocellulose for Reinforcing Alginate Fibers. BioResources. 12(4), 8180-8198.
14. Shen X. J., Huang P., Wen J., Sun R. (2017). Research status of lignin oxidative and reductive depolymerization. Prog. Chem. 29, 162-178.
15. Wang Z. K., Wen J. L., Hong S., Ma C. Y., Tang L., Jiang H., Chen J. J., Sha L., Shen X. J.,* Yuan T. Q., (2019) Lewis acid facilitate deep eutectic solvent (DES) pretreatment for producing the high-purity and antioxidative lignin. ACS Sustainable Chemistry & Engineering. 2020, 8, 1050?1057. (ESI高被引)
16. Wang Z. K., Li H. Y., Lin X. C., Tang L., Chen J. J., Jia-Wei Mo J. W., Yu R. S., Shen X. J.,* (2020) Novel recyclable deep eutectic solvent boost biomass pretreatment for enzymatic hydrolysis. Bioresource Technology. 307, 123237.
17. Cao Q. W., Wu Q., Dai L.,* Shen X. J.,* Si C. L.* (2021) A well-defined lignin-based filler for tuning the mechanical properties of polymethyl methacrylate Green Chemistry. 23, 2329-2335.
18. Xu J., Zhou P., Dai L., Yang Gui Y., Yuan L., Shen X. J.,* Zhang C. HuoK. (2021). A scalable waste-free biorefinery inspires revenue from holistic lignocellulose valorization. Green Chemistry, 23, 6008-6019.
19. Wang Z. K., Shen X. J.,* Chen J. J., Jiang Y. Q., Hu Z. Y., Wang X., Liu L. (2018). Lignocellulose fractionation into furfural and glucose by AlCl3-catalyzed DES/MIBK biphasic pretreatment. International Journal of Biological Macromolecules. 117, 721-726.
20. Jiang J., Wang C., Ebrahimi M., Shen X. J., Mei C., (2022). Eco-friendly preparation of high-quality mineralized wood via thermal modification induced silica sol penetration. Industrial Crops and Products. 183, 115003.
21. Wang Z., Huang C., Zhong J., Wang Y., Tang L., Li B., Sheng J., Chen L., Sun S., Shen X. J., (2021) Valorization of Chinese hickory shell as novel sources for the efficient production of xylooligosaccharides. Biotechnology for Biofuels. 14, 226.
22. Hong S.,# Shen X. J.,# Xue Z. M., Zhuohua Sun Z. H., Yuan T. Q. (2020), Structure–function relationships of deep eutectic solvents for lignin extraction and chemical transformation. Green Chemistry. 22, 7219-7232.
23. Shen X. J.,# Xin, Y., # Liu, H. Han, B. (2020), Product‐oriented Direct Cleavage of Chemical Linkages in Lignin. ChemSusChem. doi:10.1002/cssc.202001025.
24. Mei Q.,# Shen X. J.,# Liu H., Han B. (2019). Selectively transform lignin into value-added chemicals. Chinese Chemical Letters. 30(1), 15-24.
25. Hong S., # Shen X. J., # Zhuohua Sun Z. H., Yuan T. Q. (2020), Insights into Structural Transformations of Lignin Toward High Reactivity During Choline Chloride/Formic Acid Deep Eutectic Solvents Pretreatment. Frontiers in Energy Research. 8, 573198.[1]