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副教授/副研究员

汪璐

发布时间：2018-09-11 阅读次数: 2545

	姓　名：汪璐
	职　称：副教授/硕士生导师
	职　务：
	所属系：药物科学与工程系
	邮　箱： wanglu@hfut.edu.cn
	电　话：

个人学习工作简介

汪璐博士2005年毕业于山东大学能源与动力工程专业获得学士学位；2008年7月于中国科学院广州能源研究所环境工程专业获得硕士学位；2013年7月毕业于美国华盛顿州立大学（Washington State University）生物与农业工程专业获得博士学位。博士毕业后继续在美国华盛顿州立大学从事博士后研究。2016年2月入职金沙游戏官网。

主要研究领域与方向

1. 农林废弃物资源增值利用

2. 生物质热化学转化

获奖情况

1、2016年全国制药工程设计大赛（三等奖）

2、2018年集团公司首届微结构摄影大赛（特等奖）

3、2019年安徽省大学生生物标本制作大赛（二等奖）

4、2020年安徽省第七届工业设计大赛食品创新设计专项奖（二等奖）

5、2020年第六届全国大学生微结构摄影大赛（三等奖）

目前承担的科研项目

1、校级博士专项科研资助基金，生物质选择性热解制备液体燃料的研究，2016.05-2018.05，主持

2、安徽省自然科学基金青年项目，微波辅助农林废弃物和聚苯乙烯共催化热解制备芳香烃反应机理的研究，2017.03 – 2019.06，主持

3、集团公司学术新人提升A计划，微藻热解制备高电化学性能氮掺杂碳材料研究，2018.05 – 2019.12，主持

4、国家自然科学青年科学基金，硝酸铈预处理菊芋秸秆高效制备纳米酶/多孔碳复合材料的热解机理研究，2019.10-2022.12，主持

5、横向项目，针对白领阶层的药食同源早餐盒研发，2019.12-2020.6，主持

6、校级学术新人提升计划B项目，多孔碳球材料修饰电极对肠道短链脂肪酸的实时监测研究，2020.04-2021.12，主持

著作论文（代表作）

1) H. Wu, L. Wang*, G. Ji, H. Lei, H. Qu, J. Chen, F. Wang, J. Liu*. Renewable production of nitrogen-containing compounds and hydrocarbons from catalytic microwave-assisted pyrolysis of chlorella over metal-doped HZSM-5 catalysts. Journal of Analytical and Applied Pyrolysis. 2020,151:104902.

2) H. Qu*, Q. Ma, L. Wang, Y. Mao, M. Eisenstein, H. T. Soh*, L. Zheng. Measuring Aptamer Folding Energy Using a Molecular Clamp. J. Am. Chem. Soc. 2020, 142:11743–11749.

3) J. Chen, L. Wang, F. Wang, J. Liu*, Z. Bai*. Genomic identification of RNA editing through integrating omics datasets and the clinical relevance in hepatocellular carcinoma. Frontiers in Oncology. 2020, 1.

4) J. Yuan, Q. Shi, J. Chen, J. Lu, L. Wang, M. Qiu*, J. Liu*. Effects of 23-epi-26-deoxyactein on adipogenesis in 3T3-L1 preadipocytes and diet-induced obesity in C57BL/6 mice. Phytomedicine. 2020, 76: 153264.

5) Y. Lin, N. Yang, B. Bao, L. Wang, J. Chen, J. Liu*. Luteolin reduces fat storage in Caenorhabditis elegans by promoting the central serotonin pathway. Food Funct. 2020,29:730-740.

6) Y. Bi, L. Ye, Y. Mao, L. Wang*, H. Qu*, J. Liu*, L. Zheng*. Porous carbon supported nanoceria derived from one step in situ pyrolysis of Jerusalem artichoke stalk for functionalization of solution-gated graphene transistors for ultrasensitive and real-time detection of lactic acid from cancer cell metabolism. Biosensors & Bioelectronics. 2019,140:111271.

7) H. Qu, L. Wang*, J. Liu*, L. Zheng*, Direct Screening for Cytometric Bead Assays for Adenosine Triphosphate, ACS Sensors. 2018, 3:2071-2078.

8) L. Wang*, H. Lei*, J. Liu, Q. Bu. Thermal decomposition behavior and kinetics for pyrolysis and catalytic pyrolysis of Douglas fir. RSC Advance. 2018, 8: 2196-2202.

9) X. Zhang, H. Lei*, L. Wang, L. Zhu, Y. Wei, Y. Liu, G. Yadavalli, D. Yan. Renewable gasoline-range aromatics and hydrogen-enriched fuel gas from biomass via catalytic microwave-induced pyrolysis. Green Chemistry. 2015, 17: 4029-4036.

10) X. Zhang, H. Lei*, L. Wang, L. Zhu, Y. Wei, Y. Liu, G. Yadavalli, D Yan, J. Wu, S. Chen Production of renewable jet fuel range alkanes and aromatics via integrated catalytic processes of intact biomass. Fuel. 2015. 160:375-385.

11) Q. Bu, H. Lei*, L. Wang, G. Yadavalli, Y. Wei, X. Zhang, L. Zhu, Y. Liu. 2015. Biofuel production from catalytic microwave pyrolysis of Douglas fir pellets over ferrum-modified carbon catalyst. Journal of Analytical and Applied Pyrolysis. 2015, 112: 74-79.

12) L. Zhu, H. Lei*, L. Wang, G. Yadavalli, X. Zhang, Y. Wei, Y. Liu, S. Chen, and B. Ahring. Biochar of Corn Stover: Microwave-assisted Pyrolysis Condition Induced Changes in Surface Functional Groups and Characteristics. Journal of Analytical and Applied Pyrolysis. 2015: 149-156.

13) L. Wang, H. Lei*, Q. Bu, S. Ren, Y. Wei, L. Zhu, X. Zhang, Y. Liu, G. Yadavalli, J. Lee, S. Chen, J. Tang. Aromatic hydrocarbons production from ex situ catalysis of pyrolysis vapor over Zinc modified ZSM-5 in a packed-bed catalysis coupled with microwave pyrolysis reactor. Fuel. 2014, 129: 78-85.

14) Q. Bu, H. Lei*, L. Wang, Y. Wei, L. Zhu, X. Zhang, Y. Liu, G. Yadavalli, J. Tang, Bio-based phenols and fuel production from catalytic microwave pyrolysis of lignin by activated carbons. Bioresource Technology. 2014,162:142-147.

15) S. Ren, H. Lei*, L. Wang, G. Yadavalli, Y. Liu, J. Julson. The integrated process of microwave torrefaction and pyrolysis of corn stover for biofuel production. J. Analytic and Applied Pyrolysis. 2014, 108:248-253.

16) Y. Wei, H. Lei*, L. Wang, L. Zhu, X. Zhang, Y. Liu, S. Chen, B. Ahring. Liquid-liquid extraction of biomass pyrolysis bio-oil. Energy and Fuels. 2014,28:1207-1212.

17) Y. Wei, H. Lei*, Y. Liu, L. Wang, L. Zhu, X. Zhang, G. Yadavalli, B. Ahring, S. Chen. Renewable hydrogen produced from different renewable feedstocks by aqueous-phase reforming process. Journal of Sustainable Bioenergy Systems. 2014.4: 113-127.

18) S. Ren, H. Lei*, L. Wang, Q. Bu, S. Chen, J. Wu. Hydrocarbons and hydrogen-rich syngas production by biomass catalytic pyrolysis and bio-oil upgrading over biochar catalysts. RSC Advances. 2014.4 : 10731 – 10737.

19) L. Wang, H. Lei*, J. Lee, S. Chen, J. Tang, B. Ahring. Production of aromatic hydrocarbons from packed-bed catalysis couple with microwave pyrolysis of Douglas fir sawdust pellets. RSC Advances. 2013, 3: 14609-14615.

20) S. Ren, H. Lei*, L. Wang, Q. Bu, S. Chen, J. Wu, J. Julson, and R. Ruan. 2012. The effects of torrefaction on compositions of bio-oil and syngas from biomass pyrolysis by microwave heating. Bioresource Technology. 2013,135: 659-664.

21) S. Ren, H. Lei*, L. Wang, Q. Bu, S. Chen, J. Wu. Thermal behavior and kinetic study for woody biomass torrefaction and torrefied biomass pyrolysis by TGA. Biosystems Engineering. 2013, 116, 4: 420-426.

22) Q. Bu, H. Lei*, L. Wang, Y. Wei, L. Zhu, Y. Liu, J. Liang, J. Tang. Renewable phenols production by catalytic microwave pyrolysis of Douglas fir sawdust pellets with activated carbon catalysts. Bioresource Technology. 2013, 142: 546-552.

23) L. Wang, H. Lei*, S. Ren, Q. Bu, J. Liang, Y. Wei, Y. Liu, J. Lee, S. Chen, J. Tang, Q. Zhang, R. Ruan. Aromatics and phenols from catalytic pyrolysis of Douglas fir pellets in microwave with ZSM-5 as a catalyst. Journal of Analytical and Applied Pyrolysis. 2012, 98: 194–200.

24) S. Ren, H. Lei*, L. Wang, Q. Bu, Y. Wei, J. Liang, Y. Liu, J. Julson, S. Chen, J. Wu, and R. Ruan. Microwave torrefaction of Douglas fir pellet. Energy & Fuels. 2012, 26: 5936-5943.

25) S. Ren, H. Lei*, L. Wang, Q. Bu, S. Chen, J. Wu, J. Julson, and R. Ruan. Biofuel production and kinetics analysis of microwave pyrolysis for Douglas fir sawdust pellet. J. Analytic and Applied Pyrolysis. 2012,94: 163-169.

26) Q. Bu, H. Lei*, A.H. Zacher, L. Wang, S. Ren, J. Liang, Y. Wei, Y. Liu, J. Tang, Q. Zhang, and R. Ruan. A review of catalytic hydrodeoxygenation of lignin-derived phenols from biomass pyrolysis. Bioresource Technology. 2012, 124: 470-477.

27) Q. Bu, H. Lei*, S. Ren, L. Wang, Q. Zhang, J. Tang, and R. Ruan. Production of bio-derived phenols and biofuels from catalytic microwave pyrolysis of lignocellulosic biomass. Bioresource Technology. 2012, 108:274-279.

28) H. Lei*, S. Ren, L. Wang, Q. Bu, J. Julson, J. Holladay, and R. Roger. 2011. Microwave pyrolysis of distillers dried grain with solubles (DDGS) for biofuel production. Bioresource Technology. 2011, 102: 6208-6213.

29) Q. Bu, H. Lei*, S. Ren, L. Wang, J. Holladay, Q. Zhang, J. Tang, and R. Ruan. 2011. Phenol and phenolics from lignocellulosic biomass by catalytic microwave pyrolysis. Bioresource Technology. 2011, 102:7004-7007.

专著章节：

L. Wang, H. Lei, R. Ruan. Techno-economic analysis of microwave assisted pyrolysis for production of biofuels. Production of Biofuels and Chemicals with Microwave. Ed. F. Zhang. Springer. Biofuels and Biorefineries Volume 3, 2014, pp 251-263