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段伦博,男,1982年4月生,山东莱芜人。国家领军人才,优青、青拔。主持5项国家自然科学基金,国家重点研发计划课题1项,任务2项,973子课题1项,并获多项包括美国能源部、韩国科技部在内的外资项目资助,总资助经费超5000万元。2023年,获江苏省科技进步一等奖,2018年和2014年分别荣获教育部自然科学奖二等奖(排1和排4)。在包括NC、PECS、C&F、PCI、ES&T、CEJ等国际权威刊物上发表论文190余篇,其中SCI论文120余篇。截至2024年12月,论文引用超过6600次,个人H因子47。第1发明人申报发明专利30余项,目前授权22余项。是科技部国家重点研发计划专项专家、中国煤炭学会煤粉锅炉专业委员会委员、中国多相流检测专委会委员、中电联CFB协作网专委会委员、江苏省动力工程学会副理事长等。是Cleaner Chemical Engineering副主编、《洁净煤技术》副主编、《燃烧科学与技术》编委、《动力工程学报》青年编委、《煤炭学报》青年编委、中国工程院院刊《Engineering》青年通讯专家。是国际燃烧学会会刊Proceedings of the Combustion Institute等11个期刊的杰出审稿人。
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本科生课程:《工程热力学》、《能源与环境纵横》、《新生研讨课》;研究生全英文课:《Advanced Fuel Conversion Technology》;博士研究生课程:《循环流化床理论与运行》
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[1] 国家自然科学基金联合基金项目(重点支持项目)(U22A20435),“太阳能辅助固体材料捕集、转化CO2基础研究”,2023.01-2026.12,主持、在研。[2] 国家自然科学基金面上项目(52276106),“钛铁矿添加对流化床生物质富氧燃烧的影响机理”,2023.01-2026.12,主持、在研。[3] 江苏省碳达峰碳中和科技创新专项(前沿基础)(BK20220001),“基于固体吸收剂/催化剂的多源CO2低能耗捕集与高效转化利用基础研究”,2022.01-2024.12,主持、在研。[4] 江苏省碳达峰碳中和科技创新专项资金(重大科技成果转化)(BA2022202),“一般可燃固废协同集约处置减污降碳关键装备的研发及产业化”,2021.04-2024.12,参与(东南大学负责人)、在研。[5] 国家自然科学基金优秀青年基金项目(51922027)“煤富氧燃烧”,2020.1-2022.12,主持、在研。[6] 国家重点研发计划子课题(2019YFE0100100-08),“流化床增压O2/H2O燃烧基础研究及加压化学链燃烧过程中煤与载氧体的协同反应特性”,2020.01~2022.12,主持、在研。[7] 国家重点研发计划课题(2018YFB0605301)“常压/加压煤富氧分级燃烧、传热及污染物协调控制机理”,2018.05-2021.04,主持、结题。[8] 国家自然科学基金面上项目(51776039)“高压、高H2O浓度对流化床内煤/生物质燃烧特性的影响”,2018.1-2021.12,主持、结题。[9] 国家重点研发计划中美清洁能源联合研究中心项目课题(2016YFE0102500-06)“增压流化床富氧燃烧机理及污染物排放规律”,2016.12-2019.11,主持、结题。[10] 国家自然科学基金中美合作基金子课题(51661125011)“生物质及生物质-煤富氧燃烧过程中灰的沉积及其对传热的影响”,2016.1-2019.12,主持、结题。[11] 国家自然科学基金国际会议项目(51410305075)“第四届国际流化床富氧燃烧会议”,2014.7-2015.12,主持、结题。[12] 国家自然科学基金青年基金项目(51206023)“循环流化床O2/CO2燃烧S迁移规律研究”,2013.1-2015.12,主持、结题。[13] 国家973项目专题(2011CB707301-3)“低碳捕集成本的循环流化床富氧燃烧的理论与技术研究”,2011.01-2015.12,主持、结题。[14] 美国能源部(DOE)项目(DE-FE0029162)“干煤粉增压富氧燃烧特性研究”,2016.10-2019.09,主持、结题。[15] 韩国科技部项目(KIER-20160046)“超临界流化床富氧燃烧电站可行性研究”,2016.08-2017.08,主持、结题。[16] 外资单位出资的国际合作项目(8603000012)“2.5MWth床内换热器(IBHX)中试装置-3”,2013.12-2017.12,主持、结题。[17] 外资单位出资的国际合作项目(8603000015)“2.5MWth床内换热器(IBHX)中试装置-4”,2015.12-2017.12,主持、结题。主持教改项目:[1] 2016年教育部高等学校能源动力类专业教育教学改革项目(重点),主持;2020年东南大学第二批“课程思政”校级示范课改革试点建设项目,主持。
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[1] Peng, R., Ren, Y., Si, Y., Huang, K., Zhou, J., Duan, L. and Li, N., 2024. Strong Photothermal Tandem Catalysis for CO2 Reduction to C2H4 Boosted by Zr–O–W Interfacial H2O Dissociation. ACS Catalysis, 15, pp.1-13.[2] Deng, G., Nie, G., He, X., Li, L., Sun, Z. and Duan, L., 2024. La2O3–Modified Ni-Based Catalysts Supported on Ordered Mesoporous Silicas for CO2 Methanation. ACS Applied Nano Materials.[3] Sarmad, S., Lu, D., Gao, S., Sun, Z., Zhou, Z., Ali, A. and Duan, L., 2024. Advancing syngas production: A comparative techno-economic analysis of ICCU and CCU technologies for CO2 emission reduction. Journal of Environmental Chemical Engineering, 12(6), p.114562.[4] Li, T., Li, L., Liu, C., Liu, H., Sun, G., Ding, N., Lu, D. and Duan, L., 2024. Investigating combustion efficiency and NOx emission reduction in fluidized bed ammonia-coal co-firing. Combustion and Flame, 270, p.113735.[5] Gao, H., Wang, Y., Wang, Y., Zhou, M. and Duan, L., 2024. Understanding flame behaviors under gradient magnetic fields: The dynamics of non-reacting gas jets. International Communications in Heat and Mass Transfer, 159, p.108066.[6] Wang, Y., He, J., Wang, Y., Sun, F., Lu, C., Zhang, S. and Duan, L., 2024. Development of an integrated online deposition and corrosion monitoring system in a full-scale solid waste CFB boiler. Waste Management, 189, pp.211-218.[7] Li, X., Jiang, H., Su, Z., Xiong, L., Liang, C., Liu, D., Duan, L., Chen, H. and Chen, X., 2024. Integrated attrition model of mechanical-thermal-reaction for CaCO3/CaO thermochemical energy storage. Applied Thermal Engineering, 257, p.124247.[8] Su, Z., Jiang, H., Li, X., Du, X., Liang, C., Duan, L., Chen, H. and Chen, X., 2024. Investigation of mechanisms for heat transfer and reaction in indirectly heated CaCO3 thermochemical energy storage based on CFD-DEM. Powder Technology, p.120506.[9] Ren, Y., Si, Y., Du, M., You, C., Zhang, C., Zhu, Y.H., Sun, Z., Huang, K., Liu, M., Duan, L. and Li, N., 2024. Photothermal Synergistic Effect Induces Bimetallic Cooperation to Modulate Product Selectivity of CO2 Reduction on Different CeO2 Crystal Facets. Angewandte Chemie, p.e202410474.[10] ZHANG, Y., ZHU, C., XU, Z., ZHU, Q., YUAN, Q., LI, L., SUN, Z. and DUAN, L., 2024. Study on high-temperature absorption of potassium by ilmenite oxygen carrier. Journal of China Coal Society, 49(10), pp.4149-4158.[11] GAO, Y., WANG, W., HUANG, Z., DUAN, Y. and DUAN, L., 2024. Co-combustion characteristics of sludge and coal in fluidized beds. Journal of China Coal Society, 49(10), pp.4080-4087.[12] Li, L., Liu, C., Liu, H., Sun, G., Li, T., Lu, D. and Duan, L., 2024. Motion and Combustion Behavior of Single Char Particle in Oxy-Fuel Fluidized Bed: Experimental and Modeling Studies. Energy & Fuels, 38(21), pp.21345-21359.[13] Li, L., Sun, G., Lu, D., Liu, H., Liu, C., Jin, B. and Duan, L., 2024. Volatile-N Behavior in Oxygen Carrier Aided Solid Waste Combustion Using a Two-Stage Fluidized Bed Reactor. Energy & Fuels, 38(21), pp.21322-21332.[14] Wang, Y., Wang, Y., Zhou, M., Zhou, H. and Duan, L., 2024. The influence of self-assembled particle layer on particle collision properties. Powder Technology, 446, p.120138.[15] Wang, F., Chen, S., Yuan, P., Chen, S., Duan, L. and Xiang, W., 2024. Syngas production by biomass chemical looping gasification with composite oxygen carrier of Fe/Ce mixed phosphogypsum. Journal of Environmental Chemical Engineering, 12(5), p.114125.[16] Liu, H., Li, L., Liu, C., Sun, Z., Lu, D. and Duan, L., 2024. Quantitative Analysis of Catalytic Oxidation Reactions in Oxygen Carrier Aided Fluidized Bed Combustion. Energy & Fuels, 38(20), pp.19814-19830.[17] Xiong, L., Liu, D., Duan, L., Sun, Z., Chen, H. and Liang, C., 2024. Mass-producible γ-Al2O3/CaCO3 core–shell thermochemical energy storage particles by fluidized bed spray granulation. Chemical Engineering Journal, 495, p.153688.[18]Sun, J., Du, X., Li, Z., Yu, H., Hong, Y., Pan, M., Nie, G., Fan, W., Gao, F., Wu, F. and Li, L., Deng, G., Sun, Z. and Duan, L., 2024. Rational design of poisoning-resistant catalyst based on γ-Al2O3 for hydrolysis of carbonyl sulfide. Chemical Engineering Science, 295, p.120150.[19] Gao, H., Li, T., Wang, Y., Zhou, M., Li, L. and Duan, L., 2024. Flame structure and stability for gradient magnetic field enhanced non-premixed combustion of highly diluted methane with nitrogen. Journal of the Energy Institute, 115, p.101683.[20] Gao, H., Wang, Y., Zhou, M., Wang, Y. and Duan, L., 2024. Exploring the stabilization mechanism of NH3/CH4 non-premixed flames under gradient magnetic fields. International Journal of Hydrogen Energy, 73, pp.165-173.[21] Wang, F., Chen, S., Chen, S., Yuan, P., Duan, L. and Xiang, W., 2024. CO2 capture and H2 production performance of calcium-based sorbent doped with iron and cerium during calcium looping cycle. Process Safety and Environmental Protection.[22] Liu, B., Cheng, M., Zhang, C., Si, Y., Zhou, J., Ren, Y., Guan, J., Duan, L., Liu, M., Jing, D. and Li, N., 2024. Au-Cu Dual-single-atom Sites on Bi2WO6 with Oxygen Vacancy for CO2 Photoreduction towards Multicarbon Products. Applied Catalysis B: Environment and Energy, p.124263.[23] Ren, Y., Fu, Y., Li, N., You, C., Huang, J., Huang, K., Sun, Z., Zhou, J., Si, Y., Zhu, Y. and Chen, W., Zhu, Y., Chen, W., Duan, L. and Liu M., 2024. Concentrated solar CO2 reduction in H2O vapour with> 1% energy conversion efficiency. Nature Communications, 15(1), p.4675. [24] Niu, X., Wang, Y., Liu, H., Li, X. and Duan, L., 2024. The impact of chlorine and sulfur on alkali metal migration and submicron particle formation during solid fuel combustion. Journal of the Energy Institute, 114, p.101588.[25] Sun, G., Li, L., Duan, Y., Chen, Y., Gu, Q., Wang, Y., Sun, Z., Mao, J., Qian, X. and Duan, L., 2024. Evaluating combustion kinetics and quantifying fuel-N conversion tendency of shoe manufacturing waste. Environmental Research, 250, p.118339.[26] Liu, X., Gao, M., Zhou, Z. and Duan, L., 2024. Mitigating ash-related alkali and heavy metals emissions in rotary kiln through oxygen-carrier-aided combustion of waste. Waste Management, 181, pp.57-67.[27] Wu, W., Guío-Pérez, D.C., Bonmann, M., Johnsson, F., Duan, L. and Pallarès, D., 2024. Radar-based measurement of solids back-mixing in the freeboard of a circulating fluidized bed. Chemical Engineering Journal, 488, p.151150.[28] Zhang, M., Chen, H., Liang, C. and Duan, L., 2024. Novel technology for synergistic SO2 reduction during the carbonation process via a CaO-Char mixed system. Chemical Engineering Journal, 488, p.150678.[29] Chen, J., Ren, Y., Fu, Y., Si, Y., Huang, J., Zhou, J., Liu, M., Duan, L. and Li, N., 2024. Integration of Co Single Atoms and Ni Clusters on Defect-Rich ZrO2 for Strong Photothermal Coupling Boosts Photocatalytic CO2 Reduction. ACS nano.[30] Huang, C., Hong, Y., Wu, B., Yu, H., Du, X., Pan, M., Fan, W., Gao, F., Wu, F., Zhong, Y. and Li, L., Deng, G., Z. Sun. and Duan, L., 2024. Performance boosting by induction heating for hydrolysis of carbonyl sulfide using magnetic ordered mesoporous alumina as catalyst. Chemical Engineering Journal, 485, p.150160.[31] Wang, Y., Niu, X., Liu, H., Li, X. and Duan, L., 2024. Towards a comprehensive understanding of PM1 formation in pressurized oxy-fuel combustion: A study comparing model predictions with experimental data. Journal of the Energy Institute, 113, p.101441.[32] Zhou, Z., Huang, R., Huang, C., Nie, G., Sun, Z. and Duan, L., 2024. Non-chemically valorizing the retired cathode of ternary lithium-ion battery to high-performance oxygen carrier for chemical looping combustion. Journal of Cleaner Production, 444, p.141301.[33] Bao, Z., Lu, C., Liu, Q., Ye, F., Li, W., Zhou, Y., Pan, L., Duan, L., Tang, H., Wu, Y. and Hu, L., 2024. An acetate electrolyte for enhanced pseudocapacitve capacity in aqueous ammonium ion batteries. Nature Communications, 15(1), p.1934.[34] Deng, G., Zhou, Z., Nie, G., Huang, C., Xu, Z., Sun, Z. and Duan, L., 2024. MgO-Based Granular Sorbent Pelletized by Using Ordered Mesoporous Silica as Binder for Low-Temperature CO2 Capture. Energy & Fuels, 38(4), pp.3238-3250.[35] Li, L., Sun, G., Qi, W., Chen, Q., Sun, Z., Hao, D. and Duan, L., 2024. NOx and SO2 emission of oxygen carrier aided combustion in fluidized bed. Journal of the Energy Institute, 112, p.101463.[36] Liu, X., Duan, L., Zhou, Z. and Zhou, M., 2024. NO/SO2/HCl emissions from solid waste combustion via oxygen-carrier-aided combustion in rotary kiln. Fuel, 357, p.129902.[37] Gao, H., Li, J., Li, A., Li, Y., Xu, X., Wang, Y., Zhou, M., Wu, W. and Duan, L., 2024. Optimizing micro-diffusion flame energy density and stability through the application of magnetic fields: A numerical study. International Journal of Hydrogen Energy, 51, pp.179-189.[38] Zhou, Z., Sarmad, S., Huang, C., Deng, G., Sun, Z. and Duan, L., 2024. Ni-based catalyst supported on ordered mesoporous Al2O3 for dry CH4 reforming: Effect of the pore structure. International Journal of Hydrogen Energy, 52, pp.275-288.[39] Nie, G., Du, X., Yu, H., Fan, W., Pan, M., Gao, F., Wu, F., Hong, Y., Tang, H., Zhou, Z., Deng, G., Li. L., Sun, Z. and Duan, L., 2024. Mechanochemical transformation of spent ternary lithium-ion battery electrode material to perovskite oxides for catalytic CO oxidation. Journal of Materials Chemistry A, 12(39), pp.26877-26889.[40] Xu, Z., Zhu, C., Zhang, Y., Li, L., Sun, Z., Tang, H. and Duan, L., 2024. High-temperature potassium capture by ilmenite ore residue. Proceedings of the Combustion Institute, 40(1-4), p.105531.[41] Zhu, H., Chen, H., Zhang, M., Liang, C. and Duan, L., 2024. Recent advances in promoting dry reforming of methane using nickel-based catalysts. Catalysis Science & Technology.
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| [1] 段伦博,崔健, 陈健, 苏成林, 一种利用废白土制备脱砷吸附剂的方法,国家发明专利,201810467634.6.[2] 段伦博,苏成林,陈健,崔健,一种耦合水泥生产和废白土再利用的碳减排系统,国家发明专利,201711083562.7.[3] 段伦博,石田,陈健,一种带水合反应器的复合吸收剂循环捕捉CO2的装置及方法,国家发明专利,201810014716.5.[4] 段伦博,陈健,苏成林,石田,周琳绯,杨朋,一种面向燃气机组热电冷三联产系统的CO2捕捉方法,国家发明专利,201610638507.9.[5] 段伦博,余志健,陈健,苏成林,石田,周琳绯,一种利用Ca/Cu基复合颗粒捕集烟气中CO2的装置及方法,国家发明专利,201610320123.2.[6] 段伦博,黄恩和,王善普,曹玉,孙世超,一种烟气酸露点在线测量装置和方法,国家发明专利,201610824443.1.[7] 段伦博,苏成林,陈健,段元强,余志健,一种协同实现火电机组储能调峰和碳捕捉的装置及方法,国家发明专利,201610323102.6.[8] 段伦博,段元强,赵长遂,一种纯氧燃烧实现CO2捕集和水循环利用的方法及系统,国家发明专利,201610027301.2.[9] 段伦博,余志健,段元强,赵长遂,一种颗粒机械强度的测量装置及方法,国家发明专利,201510154252.4.[10] 段伦博,段元强,陈惠超,赵长遂,一种Cu/Ca基化合物联合循环捕捉CO2的方法及装置,国家发明专利,201410295360.9.[11] 段伦博,陈健,石田,周琳绯,赵长遂,一种低能耗实现燃气机组热电冷三联产零碳排放的方法,国家发明专利,201610825258.4.[12] 段伦博,段元强,陈惠超,赵长遂,带水合反应器的钙基吸收剂循环捕捉CO2的装置及方法,国家发明专利,201410409410.1.[13] 段伦博,段元强,陈晓平,吴新,赵长遂,一种可双向控制返料的密封反料阀,国家发明专利,201310393754.3.[14] 段伦博,韩冬,段钰锋,向文国,一种富氧燃烧热量利用的方法及装置,国家发明专利,201310154024.8.[15] 段伦博,韩冬,段钰锋,向文国,一种富氧燃烧热量梯级利用的方法及装置,国家发明专利,201310154154.1.[16] 段伦博,韩冬,段钰锋,向文国,一种富氧燃烧机组热量梯级利用的方法及装置,国家发明专利,201310154346.2.[17] 段伦博,段钰锋,赵长遂,陈晓平,桑圣欢,王卉,一种燃烟气中SOx测试方法和装置,国家发明专利,201210248424.0. |
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2024 国家万人计划领军人才2023 江苏省科技进步一等奖2021 东南大学第十一届“我最喜爱的研究生导师”之“十佳导师”2021 东南大学“杰出教学奖”之“教学新秀奖”2020 江苏省微课竞赛一等奖2020 校微课作品一等奖2019 国家自然科学基金优秀青年科学基金项目2019 教育部高等学校科学研究成果奖(自然科学奖)二等奖(排1)2019 江苏省工程热物理学会优秀青年科技工作者2018 国家“万人计划”青年拔尖人才2018 中国能源研究会优秀青年能源科技工作者奖2018 东南大学三育人积极分子2017 东南大学青年教师授课竞赛一等奖2017 东南大学中泰国立奖教金二等奖2016 东南大学“吾爱吾师—我最喜爱的老师”之能源环境学院最受欢迎老师2015 江苏省“六大人才高峰”高层次人才2014 江苏省“青蓝工程”优秀青年骨干教师2013 教育部高等学校科学研究成果奖(自然科学奖)二等奖(排4)2013 东南大学“优秀青年教师教学科研资助计划”2012 东南大学教学优秀二等奖
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已指导全日制研究生47名(包含协助指导4名),其中,硕士研究生36名(已毕业26名),博士研究生11名(已毕业3名)。所指导研究生获得江苏省优秀专业硕士学位论文1篇,东南大学优秀硕士学位论文2篇,获得包括宝钢优秀学生奖、研究生国家奖学金、江苏省优秀学生干部、博士新生奖学金、校优秀研究生干部/三好学生等荣誉多人次。 [1] 姜中孝,《水蒸气对O2/CO2燃煤特性的影响机理》,硕士研究生,2010.090-2013.05,协助指导[2] 胡海华,《增压流化床O2/CO2燃煤特性及SO2/NO排放特性试验研究》,硕士研究生,2011.09-2014.05,协助指导[3] 韩冬,《O2/CO2燃烧全流程建模及系统优化》,硕士研究生,2011.09 -2014.05,协助指导[4] 潘玄,《生物质混煤O2/CO2燃烧与污染物排放特性实验研究》,硕士研究生,2011.09 -2014.06,协助指导。[5] 孙海程,《循环流化床煤燃烧痕量元素迁移特性实验研究》,硕士研究生,2012.09-2015.06,指导[6] 段元强,《流化床增压富氧煤燃烧污染物排放特性研究》,博士研究生(硕博连续),2013.09-2020.07,指导[7] 李小乐,《蜈蚣草热处理过程中砷迁移规律研究》,硕士研究生,2014.09-2017.05,指导[8] 余志健,《成型钙基吸收剂钙循环反应活性及强度研究》,硕士研究生,2014.09-2017.05,指导[9] 陈健,《面向新型钙循环耦合CO2甲烷干重整技术的材料研制及其反应性能研究》,博士研究生(硕博连续),2015.09-2021.07,指导[10] 苏成林,《耦合水泥生产成型钙基吸收剂循环吸收CO2的性能研究》,硕士研究生,2015.09-2018.06,指导[11] 崔健,《煤与石油焦混燃的循环流化床锅炉重金属、SOx和Cl排放特性》,硕士研究生,2015.09-2018.06,指导[12] 李林,《煤颗粒流化床增压富氧燃烧机理研究》,博士研究生,2016.03-2021.05,指导[13] 石田,《纳米钙铜复合吸收剂捕捉CO2的循环反应特性及其数值模拟》,硕士研究生,2016.09-2019.06,指导[14] 薛现恒,《不同炉型 CFB 锅炉 SNCR 脱硝的现场试验与数值模拟研究》,硕士研究生,2016.09-2019.06,指导[15] 童帅,《CO2和H2O对褐煤流化床富氧燃烧的影响研究及动力学分析》,硕士研究生,2016.09-2019.06,指导[16] 王佳,《流化床增压富氧条件下AAEM及S元素在燃煤细颗粒物中的赋存特性研究》,硕士研究生,2016.09-2019.06,指导[17] 颜勇,《Oxy-CFB锅炉宽氧浓度运行策略及350MWe超临界Oxy-CFB锅炉概念设计研究》,硕士研究生,2016.09-2019.06,指导[18] 杨朋,《钙基吸收剂表面竞争吸附机理的第一性原理研究》,硕士研究生,2016.09-2019.06,指导[19] 周琳绯,《CCS技术耦合燃煤电站深度储能调峰的系统构建和性能研究》,硕士研究生,2016.09-2019.06,指导[20] 鲍中凯,《增压流化床炉内水平管传热特性研究》,硕士研究生,2017.09-2020.06,指导[21] 张奇月,《CFB机组变煤质最大出力预测研究》,硕士研究生,2017.09-2020.06,指导[22] 杨志豪,《增压富氧流化床内生物质颗粒运动及燃烧特性》,硕士研究生,2017.09-2020.06,指导[23] 卢欲晓,《铜、铈复合氧化物催化剂的火焰喷雾热解合成及催化燃烧丙烯研究》,硕士研究生,2017.09-2020.06,指导[24] 吴柯,《煤基超临界二氧化碳动力循环发电系统构建及性能研究》,硕士研究生,2017.09-2020.06,指导[25] 金弘琨,《介孔羰基硫水解催化剂的制备与性能研究》,硕士研究生,2018.09-2021.06,指导[26] 孙世超,《新型气动式旋风分离器冷态实验及数值模拟研究》,硕士研究生,2018.09-2021.06,指导[27] 石志鹏,《超低排放燃煤电厂非常规污染物迁移和排放特性研究》,硕士研究生,2018.09-2021.06,指导[28] 仇兴雷,《流化床增压富氧燃烧细颗粒物排放与沉积特性实验研究》,硕士研究生,2018.09-2021.06,指导[29] 卞若愚,《O3-NH3协同作用下活性焦低温脱硫脱硝实验研究》,硕士研究生,2018.09-2021.06,指导[30] 武万强,《待定》,博士研究生,2019.03至今,指导[31] 黄宇,《待定》,博士研究生,2019.09至今,指导[32] 刘雪,《待定》,博士研究生(定向),2019.09至今,指导[33] 洪溥,《CO2对煤流化床增压富氧燃烧的影响及同位素示踪解耦气化反应研究》,硕士研究生,2019.09-2022.06,指导[34] 吴建雯,《循环流化床富氧燃烧储能调峰系统构建与分析》,硕士研究生,2019.09-2022.06,指导[35] 周镇港,《压力对煤燃烧过程中亚微米颗粒物生成影响的数值模拟研究》,硕士研究生,2019.09-2022.06,指导[36] 高贺同,《待定》,博士研究生(硕博连续),2019.09至今,指导[37] 周智浩,《待定》,博士研究生(硕博连续),2019.09至今,指导[38] 包旭,《待定》,硕士研究生,2020.09至今,指导[39] 黄超,《待定》,硕士研究生,2020.09至今,指导[40] 徐昊,《待定》,硕士研究生,2020.09至今,指导[41] 李天新,《待定》,博士研究生(硕博连续),2020.09至今,指导[42] 厉志鹏,《待定》,博士研究生,2021.09至今,指导[43] 王煜兴,《待定》,博士研究生(硕博连续),2021.09,指导[44] 牛晓雪,《待定》,硕士研究生,2021.09至今,指导[45] 陆佳慧,《待定》,硕士研究生,2021.09至今,指导[46] 张雨琪,《待定》,硕士研究生,2021.09至今,指导[47] 徐禛,《待定》,博士研究生(硕博连续),2021.09至今,指导[48] 刘恒,《待定》,硕士研究生,2022.09至今,指导[49] 刘崇,《待定》,硕士研究生,2022.09至今,指导[50] 范圣玮,《待定》,硕士研究生,2022.09至今,指导
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