个人简介
华中科技大学,能源与动力工程学院,副教授,博导,工学博士,伦敦帝国理工学院博士后。2009年9月-2013年6月在华中科技大学煤燃烧国家重点实验室攻读博士学位。2013年7月-2014年10月,于烟台龙源电力技术股份有限公司从事燃煤锅炉燃烧数值模拟等方面的研究工作。2014年11月-2017年2月,在英国帝国理工学院进行博士后研究工作,师从于Marcos Millan-Agorio教授,开展了生物质和固体废弃物热处理方面的研究。承担多项国家课题;在国际知名期刊以第一和通作者共发表30余篇学术论文。
教育及工作经历
2018.11—至今 华中科技大学,副教授
2017.03—2018.10 华中科技大学,讲师
2014.11—2017.02 伦敦帝国理工学院,博士后,合作导师:Marcos Millan
2009.09—2013.06 华中科技大学,热能工程专业,博士
科研项目:
1、 危废热利用过程中污染物迁移转化机制 国家重点研发计划(科技部)子任务主持 115万 2018.12-2022.12
2、 煤粉热解活性还原组份生成及反应机制 国家重点研发计划(科技部) 子任务主持72.35万 2018.05-2020.10
3、 废旧轮胎催化热解过程中有机硫化物与催化剂和特征主体组份交互作用机制 国家自然科学基金(青年项目)主持 25万 2019.01-2021.12
4、 生活垃圾分类回收,梯级利用技术研究 主持 武汉市 (5万)
5、 企业项目:湖北金盛兰120万吨球团SNCR数值模拟 主持(8万)
6、 企业项目:燃烧电厂SCR机组氨逃逸迁移、危害及防治技术研究辅助研究项目 主持(26万)
所获荣誉和奖励
指导本科生获得第十三届全国大学生节能减排大赛一等奖
近期论文
查看导师新发文章
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[1] Yu, J., D. Wang, and L. Sun, The pyrolysis of lignin: Pathway and interaction studies. Fuel, 2021. 290.
[2] Wei, X., et al., New insights into the pyrolysis behavior of polycarbonates: A study based on DFT and ReaxFF-MD simulation under nonisothermal and isothermal conditions. Energy and Fuels, 2021. 35(6): p. 5026-5038.
[3] Sun, L., et al., Preparation of sorbents derived from bamboo and bromine flame retardant for elemental mercury removal. Journal of Hazardous Materials, 2021. 410.
[4] Han, Y., et al., Study on catalytic pyrolysis mechanism of natural rubber (NR) over Zn-modified ZSM5 catalysts. Journal of the Energy Institute, 2021. 94: p. 210-221.
[5] Yu, J., et al., The Interaction of NH4HSO4 with Vanadium-Titanium Catalysts Modified with Molybdenum and Tungsten. Energy and Fuels, 2020. 34(2): p. 2107-2116.
[6] Yu, J., CHAPTER 7: Catalysis in Modern Bio-refineries: Towards a New Bio-energy Paradigm. RSC Energy and Environment Series, 2020. 2020-January(27): p. 180-201.
[7] Chen, T., et al., Catalytic performance and debromination of Fe–Ni bimetallic MCM-41 catalyst for the two-stage pyrolysis of waste computer casing plastic. Chemosphere, 2020. 248.
[8] Bikane, K., et al., Early-stage kinetics and char structural evolution during CO2 gasification of Morupule coal in a wire-mesh reactor. Chemical Engineering Journal, 2020.
[9] Bikane, K., et al., Linking char reactivity to structural and morphological evolution during high pressure pyrolysis of Morupule coal. Chemical Engineering Science: X, 2020. 8.
[10] Yu, J., et al., Experimental research on denitrification and elemental mercury removal by Surface Dielectric Barrier Discharge. Process Safety and Environmental Protection, 2019. 125: p. 307-316.
[11] Yu, J., N. Paterson, and M. Millan, The primary products of cellulose pyrolysis in the absence of extraparticle reactions. Fuel, 2019. 237: p. 911-915.
[12] Yu, J., J.A. Odriozola, and T.R. Reina, Dry reforming of ethanol and glycerol: Mini-review. Catalysts, 2019. 9(12).
[13] Yu, J., et al., Catalytic pyrolysis of rubbers and vulcanized rubbers using modified zeolites and mesoporous catalysts with Zn and Cu. Energy, 2019. 188.
[14] Ma, C., et al., The behavior of heteroatom compounds during the pyrolysis of waste computer casing plastic under various heating conditions. Journal of Cleaner Production, 2019. 219: p. 461-470.
[15] Yu, J., et al., Influence of temperature and particle size on structural characteristics of chars from Beechwood pyrolysis. Journal of Analytical and Applied Pyrolysis, 2018. 130: p. 249-255.
[16] Ma, C., et al., Influence of Fe based ZSM-5 catalysts on the vapor intermediates from the pyrolysis of brominated acrylonitrile-butadiene-styrene copolymer (Br-ABS). Fuel, 2018. 230: p. 390-396.
[17] Liu, S., et al., Rubber pyrolysis: Kinetic modeling and vulcanization effects. Energy, 2018. 155: p. 215-225.
[18] Yu, J., et al., Cellulose, xylan and lignin interactions during pyrolysis of lignocellulosic biomass. Fuel, 2017. 191: p. 140-149.
[19] Ma, C., et al., Pyrolysis-catalytic upgrading of brominated high impact polystyrene over Fe and Ni modified catalysts: Influence of HZSM-5 and MCM-41 catalysts. Polymer Degradation and Stability, 2017. 146: p. 1-12.
[20] Ma, C., et al., Catalytic pyrolysis of flame retarded high impact polystyrene over various solid acid catalysts. Fuel Processing Technology, 2017. 155: p. 32-41.
[21] Yu, J., et al., Study on the behavior of heavy metals during thermal treatment of municipal solid waste (MSW) components. Environmental Science and Pollution Research, 2016. 23(1): p. 253-265.
[22] Yu, J., et al., Thermal degradation of PVC: A review. Waste Management, 2016. 48: p. 300-314.
[23] Yu, J., et al., Mechanism on heavy metals vaporization from municipal solid waste fly ash by MgCl2•6H2O. Waste Management, 2016. 49: p. 124-130.
[24] Ma, C., et al., Influence of Zeolites and Mesoporous Catalysts on Catalytic Pyrolysis of Brominated Acrylonitrile-Butadiene-Styrene (Br-ABS). Energy and Fuels, 2016. 30(6): p. 4635-4643.
[25] Ma, C., et al., Chemical recycling of brominated flame retarded plastics from e-waste for clean fuels production: A review. Renewable and Sustainable Energy Reviews, 2016. 61: p. 433-450.
[26] Chen, Z., et al., Gasification of torrefied kitchen waste: release of sodium and its influence on the formation of gasification products. Asia-Pacific Journal of Chemical Engineering, 2016. 11(5): p. 785-794.
[27] Yu, J., et al., Detoxification of ashes from a fluidized bed waste incinerator. Chemosphere, 2015. 134: p. 346-354.
[28] Yu, J., et al., Removal of toxic and alkali/alkaline earth metals during co-thermal treatment of two types of MSWI fly ashes in China. Waste Management, 2015. 46: p. 287-297.
[29] Yu, J., et al., New method of quantitative determination of the carbon source in blast furnace flue dust. Energy and Fuels, 2014. 28(11): p. 7235-7242.
[30] Yu, J., et al., Physical and chemical characterization of ashes from a municipal solid waste incinerator in China. Waste Management and Research, 2013. 31(7): p. 663-673.
[31] Yu, J., et al., Kinetic vaporization of heavy metals during fluidized bed thermal treatment of municipal solid waste. Waste Management, 2013. 33(2): p. 340-346.
[32] Yu, J., et al., Vaporization of heavy metals during thermal treatment of model solid waste in a fluidized bed incinerator. Chemosphere, 2012. 86(11): p. 1122-1126.