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复旦大学环境科学与工程系导师教师师资介绍简介-李庆

本站小编 Free考研考试/2021-01-10

李庆 青年研究员/博士生导师
邮箱:qli@fudan.edu.cn
电话:
个人简历
2012年6月清华大学工程物理系获工学博士学位,随后在清华大学环境学院和日本广岛大学等从事博士后和客座研究员等研究工作,2017年2月加入复旦大学环境科学与工程系,任职青年研究员。
教学课程
本科生:《大气污染控制》。
研究生:《燃烧源污染控制》。
主要研究方向:重点源排放气溶胶及其控制
(1)固体燃烧源的非常规大气污染物形成与控制,如,工业燃煤和钢铁冶炼过程中SO3、HCl、NH3等可冷凝颗粒物的形成机理与控制技术;
(2)柴油内燃机的有机气溶胶和气态污染物形成与控制,如,船舶油品、发动机运转和污染控制技术对气溶胶和VOCs的影响评估;
(3)农村散乱面源污染评估和控制方法的研究,如,生物质和民用煤燃烧的排放与改进燃烧技术研发。

近期主要科研项目
(1) 国家自然科学基金面上项目(**):典型燃煤电厂和钢铁厂的SO3排放特征及其对颗粒物老化影响的研究,2019.1~2022.12,主持;
(2) 国家自然科学基金青年项目(**):货运船舶排放典型气态与颗粒态污染物组分特征的研究,2019.1~2021.12,主持;
(3) 国家重点研发计划“大气污染成因与控制技术研究”(2018YFC**):“长三角PM2.5和臭氧协同防控策略与技术集成示范” ,2018.7~2021.6,参与;
(4) 上海市自然科学基金面上项目(18ZR**):典型货运船舶排放细颗粒物的特征及其对上海空气质量的影响研究,2018.6~2021.5,主持;
(5) 国家自然科学基金重点研究计划(**):长三角代表性城市大气细颗粒样品的采集及其表征与解析,2018.1~2021.12,参与;
(6) 复旦大学人才引进项目(JIH**):大气污染源排放特征与控制原理,2017.2~2019.12,主持。
期刊审稿
Environmental Science & Technology, Atmospheric Chemistry and Physics, Environment International, Environmental Pollution, Atmospheric Environment, Science of Total Environment, Aerosol Science & Technology, Nanoscale等十多个环境领域主流期刊审稿。
第一/通讯的期刊论文
[1].X. Ding, Q. Li*, D. Wu, Y. Liang, X. Xu, G. Xie, Y. Wei, H. Sun, C. Zhu, H. Fu, and J. Chen*, “Unexpectedly Increased Particle Emissions from the Steel Industry Determined by Wet/Semidry/Dry Flue Gas Desulfurization Technologies”, Environ. Sci. Tech. doi.org/10.1021/acs.est.9b03081 (2019).
[2].D. Wu, X. Ding, Q. Li*, J. Sun, C. Huang, L. Yao, X. Wang, X. Ye, Y. Chen, H. He, and J. Chen*, “Pollutants emitted from typical Chinese vessels: potential contributions to ozone and secondary organic aerosols”, J. Clean. Prod. 238, 117862 (2019).
[3].L. Chen, Q. Li*, D. Wu, H. Sun, Y. Wei, X. Ding, H. Chen, T. Cheng, and J. Chen*, “Size distribution and chemical composition of primary particles emitted during open biomass burning processes: Impacts on cloud condensation nuclei activation”, Sci. Total Environ. 674, 179 (2019).
[4].Q. Li#, J. Qi#, J. Wu, J. Jiang, L. Duan, S. Wang, and J. Hao, “Significant reduction in air pollutant emissions from household cooking stoves by replacing raw solid fuels with their carbonized products”, Sci. Total Environ. 650, 653 (2019).
[5].D. Wu, Q. Li*, X. Ding, J. Sun, D. Li, H. Fu, M. Teich, X. Ye, and J. Chen*, “Primary Particulate Matter Emitted from Heavy Fuel and Diesel Oil Combustion in a Typical Container Ship: Characteristics and Toxicity”, Environ. Sci. Tech. 52, 12943 (2018).
[6].Q. Li, C. W. Kartikowati, S. Horie, T. Ogi, T. Iwaki, and K. Okuyama, “Correlation between particle size/domain structure and magnetic properties of highly crystalline Fe3O4 nanoparticles”, Sci. Rep. 7, 9894 (2017).
[7].Q. Li, T. Ogi, C. W. Kartikowati, T. Iwaki, and K. Okuyama, “Facile fabrication of carbon nanotube forest films via coaxial electrospray”, Carbon 115, 116 (2017).
[8].Q. Li, J. Jiang, S. Wang, K. Rumchev, R. Mead-Hunter, L. Morawska, and J. Hao, “Impacts of Household Solid Fuel Combustion on Indoor and Ambient Air Quality in China: Current Status and Implication”, Sci. Total Environ. 576, 347 (2017).
[9].J. Qi#, Q. Li#, J. Wu, J. Jiang, Z. Miao, and D. Li, “Bio-Coal Briquette Combusted in a Household Cooking Stove: Improved Thermal Efficiency and Reduced Pollutant Emissions”, Environ. Sci. Tech. 51, 1886 (2017).
[10].Q. Li, J. Jiang, S. Cai, W. Zhou, S. Wang, L. Duan, and J. Hao, “Gaseous Ammonia Emissions from Coal and Biomass Combustion in Household Stoves with Different Combustion Efficiencies”, Environ. Sci. Tech. Lett. 3, 164 (2016).
[11].Q. Li, X. Li, J. Jiang, L. Duan, S. Ge, Q. Zhang, J. Deng, S. Wang, and J. Hao, “Semi-coke briquettes: towards reducing emissions of primary PM2.5, elemental/organic carbon, and carbon monoxide from household coal combustion in China”, Sci. Rep. 6, 19306 (2016).
[12].Q. Li, J. Jiang, J. Qi, J. Deng, D. Yang, J. Wu, L. Duan, and J. Hao, “Improving Stove Energy Efficiency to Reduce Pollutant Emission from Household Solid Fuel Combustion in China”, Environ. Sci. Tech. Lett. 3, 369 (2016).
[13].Q. Li, J. Jiang, Q. Zhang, W. Zhou, S. Cai, L. Duan, S. Ge, and J. Hao, “Influences of Coal Size, Volatile Matter Content, and Ash Content on Primary Particulate Matter Emissions from Household Stove Combustion”, Fuel 182, 780 (2016).
[14].李庆, 段雷,蒋靖坤,王书肖,郝吉明, “我国民用燃煤一次颗粒物的减排潜力研究”, 中国电机工程学报 36, 4408 (2016).
[15].Q. Li, J. Jiang, L. Duan, J. Deng, L. Jiang, Z. Li, and J. Hao, “Improving the removal efficiency of elemental mercury by pre-existing aerosol particles in double dielectric barrier discharge treatments”, Aerosol Air Qual. Res. 15,1506 (2015).
[16].Q. Li, J. Jiang, and J. Hao, “A review of aerosol nanoparticle formation from ions”, KONA Powder Particle J. 32, 57 (2015).
[17].Q. Li, H. Takana, Y. K. Pu, and H. Nishiyama, “Glow-like helium and filament-like argon plasma jets of using a dielectric barrier configuration at atmospheric pressure”, IEEE Trans. Plasma Sci. 42, 2360 (2014).
[18].Q. Li, H. Takana, Y. K. Pu, and H. Nishiyama, “A nonequilibrium argon-oxygen planar plasma jet using a half-confined dielectric barrier duct in ambient air”, Appl. Phys. Lett. 100, 133501 (2012).
[19].Q. Li, H. Takana, Y. K. Pu, and H. Nishiyama, “An atmospheric pressure quasi-uniform planar plasma jets by using a dielectric barrier configuration”, Appl. Phys. Lett. 98, 241501 (2011).
[20].Q. Li, Y. K. Pu, M. A. Lieberman, and D. Economou, “Dynamic model of streamer coupling for the homogeneity of glow-like dielectric barrier discharges at near-atmospheric pressure”, Phys. Rev. E 83, 046405 (2011).
[21].Q. Li, Y. K. Pu, and H. Nishiyama, “Atmospheric pressure dielectric barrier plasma jets elongated by elevating external electric field”, IEEE Trans. Plasma Sci. 39, 2290 (2011).
[22].Q. Li, W. C. Zhu, X. M. Zhu, and Y. K. Pu, “Effects of Penning ionization on the discharge patterns of atmospheric pressure plasma jets”, J. Phys. D: Appl. Phys. 43, 382001 (2010).
[23].Q. Li, X. M. Zhu, J. T. Li, and Y. K. Pu, “Role of metastable atoms in the propagation of atmospheric pressure dielectric barrier discharge jets”, J. Appl. Phys. 107, 043304 (2010).
[24].Q. Li, J. T. Li, X. M. Zhu, W. C. Zhu, and Y. K. Pu, “Effects of gas flow rate on the length of atmospheric pressure nonequilibrium plasma jets”, Appl. Phys. Lett. 95, 141502 (2009).
欢迎对以上研究方向感兴趣的同学加入我们团队,攻读硕士/博士学位或博士后等研究工作。




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