基本信息

高宁博,博士生导师,副教授

联系方式

邮编:710049

邮箱:nbogao@xjtu.edu.cn

办公电话:0086 29 82668572

办公地点:兴庆教学二区化工楼422室

社会兼职

1. 国家自然科学基金函评专家;

2. 陕西省科技厅评审专家;

3. 国际期刊 Biomed Research International责任编辑, Journal of Chemistry客座编辑;

4. Applied Energy, Environment Science & Technology, Fuel, Journal of Cleaner Production, Thermochimica Acta, Industrial & Engineering Chemistry Research, Energy Conversion and Management, Fuel Processing Technology, Journal of Analytical and Applied Pyrolysis, Waste Management, The Canadian Journal of Chemical Engineering,化工学报, 环境科学, Chinese Science Bulletin等期刊审稿人。

招聘/招生信息

招生:每年招收博士生、硕士生若干名,欢迎具有环境、热能、催化、化工等背景的同学加入。

 

站点计数器
研究领域

1. 固体废物处理及资源化;

2. 生活垃圾处理及能源化利用;

3. 含油污泥无害化与资源化利用;

4. 生物质/煤气化、热解及污染物控制;

5. 焦油催化重整制氢;

6. 市政/工业污泥处理及资源化;

7. 有机固体废物生物处理技术

教育、工作经历

2016/06-至今        西安交通大学能动学院,博士生导师

2016/08-2017/07  英国赫尔大学化工学院,访问学者

2015/12-至今        西安交通大学能动学院,副教授,硕士生导师

2011/04-2015/12  大连理工大学环境学院,讲师,硕士生导师

2009/03-2011/04  大连理工大学环境学院,讲师,师资博士后

2005/03-2009/02  大连理工大学能源与动力学院,热能工程,工学博士

负责的科研项目

近年主持的部分科研课题
25. 陕西省联合基金项目-陕煤联合基金项目重点项目,2019JLZ-12
24. 欧盟EU-RISE 2020 Horizon Project,项目号:823745 — BIOMASS-CCU — H2020-MSCA-RISE-2018,2019-2022
23. 中国博士后科学基金特别资助,项目号: 2018T111070, 2018-2020 
22. 陕西省博士后基金一等资助,2018-2019 
21. 企业委托技术开发课题, 2017-2018
20. 石油石化污染控制与处理国家重点实验室技术开发合同,2017-2019
19. 陕西省科技计划项目-工业攻关,2017-2020
18. 中国博士后基金一等资助,2017-2019
17. 西安交通大学本科教学改革项目,2016-2018
16. 中央高校基本科研业务费学科综合交叉项目, 2016-2018
15. 教育部一流大学建设 环境工程学科创新平台建设,2016-2017
14. 西安交通大学教师支持计划,2016-2019
13. 国家自然科学基金面上项目,项目号: 51476023, 2015-2018
12. 国家自然科学基金青年基金,项目号: 51006018, 2010-2013
11. 国家自然科学基金国际(地区)合作与交流项目,项目号: 51011140584, 2011-2012
10. 中国博士后科学基金特别资助,项目号: 201003616, 2010-2014
9. 中国博士后基金面上资助,项目号: 20090451264, 2009-2012
8. 辽宁省教育厅科学技术研究项目,项目号: L2013027, 2013-2015

 

获奖

12. 2020年学术论文获得陕西省第十四届自然科学优秀学术论文二等奖,高宁博,全翠,刘宝玲,李宗阳,吴春飞,基于螺旋反应器的污泥连续热解: 产物特性和重金属的生态风险评价(Continuous pyrolysis of sewage sludge in a screw-feeding reactor: products characterization and ecological risk assessment of heavy metals).

11. 2019, Janpan-China-Korea Joint Symposium, Development of activated biochar supported Ni catalyst for enhancing tar steam reforming, 2019.9.4-7, Tokyo, Japan. 优秀墙报奖; 

10. 2018年,The 6th International Symposium on Gasification and its Application (ISGA-6), 2018.10.25-28,Chengdu, China. 优秀墙报奖;

9. 2014年,学术论文“Characteristics of hydrogen-rich gas production of biomass gasification with porous ceramic reforming“,获辽宁省自然科学学术成果一等奖;
8. 2010年,学术论文“上吸式固定床生物质水蒸气气化多孔陶瓷重整制氢研究”获辽宁省自然科学学术成果二等奖;
7. 2010年,学术论文“Modeling and simulation of combined pyrolysis and reduction zone for a downdraft biomass gasifier”,获大连市自然科学优秀学术论文三等奖;
6. 2014年获大连理工大学优秀本科毕业论文指导教师奖;
5. 2014年获大连理工大学校工作量考核优秀教师;
4. 2013年获大连理工大学化工环境与生命学部优秀教师;
3. 2012年大连理工大学创新创业训练计划“优秀指导教师”称号;
2. 2012年指导的本科生获得“辽宁省第十一届“挑战杯”辽宁省大学生课外学术科技作品竞赛”省二等奖;
1. 2012年指导的本科生获得“第四届高校环保科技创意设计大赛”,银奖。
专利

38. 高宁博, 陈凯轮, 全翠, 一种高含水率有机物的水热脱水处理反应装置及其操作方法, 发明,实审 

37. 高宁博,程丽杰,全翠, 一种高氯酸铵废水的处理方法, 2019113206024, 2019-12-19,发明,实审  

36. 高宁博,段一航,全翠, 一种废弃含能材料的处理方法, 2019113205888, 2019-12-19,发明,实审  

35. 高宁博,王凤超,全翠, 一种有机固体废物两级还原热解制备改性活性炭的方法、系统和应用, 201910943536X, 2019-09-30,发明,实审  

34. 高宁博,李家琦,全翠, 有机固体燃料热解、气化及焚烧一体化装置及处理方法, 2019102493646, 2019-03-29,发明,授权  

33. 高宁博,李宗阳,全翠, 一种含尘油气的除尘装置及除尘方法, 2019101810668, 2019-03-11, 2020-04-28, 发明, 授权  

32. 高宁博,段一航,全翠, 一种旋风除尘装置及其操作方法, 2019101810916, 2019-03-11, 2020-03-17, 发明, 授权  

31. 高宁博,李宗阳,全翠, 一种用于高含水率有机物处理的装置及方法, PCT/CN2018/115440, 2018-11-14,发明,已递交  

30. 高宁博,李宗阳,全翠, 一种用于高含水率有机物处理的装置及方法, 2018108479760, 2018-07-27,发明,授权  

29. 高宁博,李宗阳,全翠, 水热脱水处理高含水率有机物的反应釜及连续式系统, 201621310662X, 2016-12-01, 2017-08-01, 实用新型, 授权  

28. 高宁博,李宗阳,全翠, 水热脱水处理高含水率有机物的反应釜、连续式系统及方法, 2016110912578, 2016-12-01,发明,已递交  

27. 高宁博,韩映,全翠, 一种陶瓷膜氧化还原反吹系统, 2016204741303, 2016-05-23, 2016-11-30, 实用新型, 授权  

26. 高宁博,韩映,全翠, 一种陶瓷膜氧化还原反吹系统及方法, 2016103483173, 2016-05-23, 2018-08-10, 发明, 授权  

25. 全翠,苏瑞瑞,高宁博, 一种耦合处理高浓度有机废水和重金属废水的方法, 2018116427452, 2018-12-29,发明,授权  

24. 高宁博;李宗阳;全翠,一种有机固体燃料内除尘式热解气化装置与方法,发明,(201510381567.2),已授权.

23. 高宁博,郝乔, 尹志凡, 一种磁稳定催化重整方法与装置(201210326137.7),已授权.

22. 高宁博, 刘爽, 李爱民, 张雷, 一种有机液体燃料雾化催化重整方法及装置,(201310025747.8) 已授权.

21. 高宁博, 刘保玲,李爱民, 一种催化陶瓷膜反应装置, 发明/实用新型, 201410492167.4/201420549511.4, 已授权.

20. 多孔陶瓷高温带压水蒸气制备装置(200610200415.9),已授权.

19. 超绝热部分氧化焦油焦碳清除及气体重整方法与装置(200810012601.9), 已授权.

18. 一种有机废物制取活性炭一体化装置及方法 (200910310173.2) ,已授权.

17. 一种有机物两级干燥与气化一体化的装置及方法(201110062338.6),已授权.

16. 一种有机固体燃料干燥、热解焚烧一体化方法与装置,(201210387495.9), 已授权.

15. 一种连续式制备活性炭的一体化装置(ZL 201320434911.6),中国,实用新型,2013-11,已授权.

14. 一种除尘、催化一体化装置(201410490544.0), 发明,已授权.

13. 一种连续式制备活性炭的一体化装置及方法,201310306054.6,已授权.

12. Method for preparation of active carbon by pyrolysis of organics. 2013, PAT US8563467 (US9650254-B2), 已授权,(美国专利).

11. 一种有机固体废物气化焚烧一体化方法及装置. 发明专利, 2014. 201410069870.4, 已授权.

10.  一种堆叠式换热器, 实用新型, 2014, 201410491310.8/201420549623.X, 已授权.

9. 一种整体式换热器及其加工方法, 发明,201410490710.7, 已授权.

7. 一种隧道窑的制砖方法, 发明, 201410491306.1, 已授权.

6.  一种垃圾压制成型方法及切削式造粒装置, 发明/实用新型, 201410490543.6/201420549345.8, 已授权.

5.  一种有机固体废物焚烧一体化装置及方法, 发明/实用新型, 201410490545.5/201420550004.2, 已授权.

4. 一种有机物热解制取活性炭方法,201110083062.X, 已授权.

3. 一种翻转床热固载体热解析装置(200910304367.1) , 已授权.

2. 一种采用多孔陶瓷的消泡方法,(201010152892.9),已授权.

1. 一种利用熔融盐活化制备活性炭的方法,201410350867.X,已授权. 

 

代表性学术论文

[96] Miskolczi, N., Zsinka, V., Tóth, O., Eller, Z., Gao, N., Cui, Q., Bobek, J. Co-pyrolysis-reforming of biomass and residues from waste polymer pyrolysis for CO2 reduction and syngas enhancement. Chemical Engineering Transactions, 2020, 81: 1195-1200.

[95] 程丽杰, 高宁博*, 楚华, 等 . 高氯酸盐还原菌的代谢过程及应用研究进展. 化工进展, 2020, 39(S2): 259-269. (CHENG Lijie, GAO Ningbo, CHU Hua, et al. Metabolism and application of perchlorate reducing bacteria in microbial reduction of perchlorate: a review. Chemical Industry and Engineering Progress, 2020, 39(S2): 259-269.)

[94] Ningbo Gao*, Yihang Duan, Zongyang Li, Cui Quan, Kunio Yoshikawa, Hydrothermal treatment combined with in-situ mechanical compression for floated oily sludge dewatering, Journal of Hazardous Materials,2020, 124173. doi:https://doi.org/10.1016/j.jhazmat.2020.124173. (SCI/EI, IF= 9.038, Top) 

[93] Ningbo Gao*Kamran Kamran, Zhengzhao Ma, Cui Quan. Investigation of product distribution from co-pyrolysis of side wall waste tire and off-shore oil sludge. Fuel, 2021, 285: 119036. https://doi.org/10.1016/j.fuel.2020.119036. (SCI, IF=5.578, Top). 

[92] Zeeshan Hameed, Dr.Salman Naqvi, Muhammad Naqvi, Imtiaz Ali, Syed Ali Taqvi, Ningbo Gao, Syed Azfar Hussain and Sadiq Hussain. A comprehensive review on thermal co-conversion of biomass, sludge, coal and their blends using thermogravimetric analysis, Journal of Chemistry, 2020,  https://doi.org/10.1155/2020/5024369. (SCI/EI, IF=1.79)

[91] Yuanting Qiao, Shuming Zhang, Cui Quan*, Ningbo Gao, Chris Johnston, Chunfei Wu. One-pot synthesis of digestate-derived biochar for carbon dioxide capture, Fuel, 2020, Doi: https://doi.org/10.1016/j.fuel.2020.118525 (SCI, IF=5.578, Top). 

[90] Ningbo Gao*, Ayesha Tariq Sipra, Cui Quan. Thermogravimetric analysis and pyrolysis product characterization of municipal solid waste using sludge fly ash as additive, Fuel, 2020, Doi: https://doi.org/10.1016/j.fuel.2020.118572. (SCI, IF=5.578, Top). 

[89] 高宁博*陈凯轮全翠固体废物处理与处置课程创新教学与实践环境工程, 2020. 出版中.

[88] 宁永安段一航,高宁博*全翠煤气化渣组分回收与利用技术研究进展洁净煤技术, 2020. 出版中.

[87] Janka Bobek-Nagy, Gao Ningbo*, Cui Quan, Norbert Miskolczi*, Dóra Rippel-Pethő, Kristóf Kovács. Catalytic co-pyrolysis of packaging plastic and wood waste to achieve H2 rich syngas. International Journal of Energy Research, 2020, http://dx.doi.org/10.1002/er.5741. (SCI, IF= 3.741, Top). 

[86] 高宁博*陈凯轮全翠废锂离子电池回收与综合利用研究进展环境工程, 2020. 出版中.

[85] Ningbo Gao*; Jiaqi Li; Cui Quan; Xiao Wang; Yang Yang, Oily sludge catalytic pyrolysis combined with fine particle removal using a Ni-ceramic membrane, Fuel, 2020, Doi:http://dx.doi.org/10.1016/j.fuel.2020.118134. (SCI, IF= 5.578, Top). 

[84] Ningbo Gao*; Xiangyu Jia; Guanqun Gao; Zhengzhao Ma; Cui Quan; Salman R Naqvi, Modeling and simulation of coupled pyrolysis and gasification of oily sludge in a rotary kiln, Fuel, 2020, Doi: https://doi.org/10.1016/j.fuel.2020.118152 (SCI, IF= 5.578, Top). 

[83] Shuming Zhang; Ningbo Gao*; Cui Quan; Fengchao Wang; Chunfei Wu*. Autothermal CaO looping biomass gasification to increase process energy efficiency and reduce ash sintering, Fuel, 2020, Doi: https://doi.org/10.1016/j.fuel.2020.118199. (SCI, IF= 5.578, Top). 

[82] Yue Chai, Meihong Wang, Ningbo Gao*, Yihang Duan, Jiaqi Li. Experimental Study on Pyrolysis/Gasification of Biomass and Plastics for H2 Production under New Dual-support Catalyst, Chemical Engineering Journal, 2020, Doi: https://doi.org/10.1016/j.cej.2020.125260. (SCIIF= 10.652, Top).

[81] Ningbo Gao*, Kamran Kamran, Cui Quan, Paul Williams. Thermochemical Conversion of Sewage Sludge: A Critical Review. Progress in Energy and Combustion Science, 2020,79:100843. Doi: https://doi.org/10.1016/j.pecs.2020.100843. (SCI/EI, IF= 28.938, Top). 

[80] Ningbo Gao*, Mingxing Chen, Cui Quan, Syngas production via combined dry and steam reforming of methane over Ni-Ce/ZSM-5 catalyst, Fuel, 2020, Doi: https://doi.org/10.1016/j.fuel.2020.117702. (SCI, IF= 5.578, Top). 

[79] Małgorzata Sieradzka*, Ningbo Gao*, Cui Quan, Agata Mlonka-Mędrala and Aneta Magdziarz. Biomass thermochemical conversion via pyrolysis with integrated CO2 capture, Energies 202013(5), 1050. https://doi.org/10.3390/en13051050 (SCI, IF= 2.707). 

[78] Cui Quan, Huihui Wang, Ningbo Gao*. Development of activated biochar supported Ni catalyst for enhancing toluene steam reforming. International Journal of Energy Research, 2020, DOI:10.1002/er.5335. (SCI, IF= 3.741, Top). 

[77] Cui Quan, Ruirui Su, Ningbo Gao*. Preparation of activated biomass carbon from pine sawdust for supercapacitor and CO2 capture. International Journal of Energy Research, 2020, DOI:10.1002/er.5206. (SCI, IF= 3.741, Top). 

[76] Ningbo Gao*, Jiaqi Li, Cui Quan, Houzhang Tan. Product property and environmental risk assessment of heavy metals during pyrolysis of oily sludge with fly ash additive, Fuel, 2020, https://doi.org/10.1016/j.fuel.2020.117090. (SCI, IF= 5.578, Top). 

[75] 全翠,王惠惠,高宁博,煤热解条件因素与油气产物改性提质技术研究,煤炭科学与技术,2020,录用.

 

[74] Fengchao, Wang, Ningbo Gao*, Cui Quan, Gartzen López. Investigation of hot char catalytic role in the pyrolysis of waste tires in a two-step process. Journal of Analytical and Applied Pyrolysis. 2019 https://doi.org/10.1016/j.jaap.2019.104770. (SCIIF= 3.905, Top).

[73] Cui Quan, Xiangyu Jia, Ningbo Gao*. Nitrogen doping activated biomass carbon from tea seed shell for CO2 capture and supercapacitor. International Journal of Energy Research, 2019, https://doi.org/10.1002/er.5017. (SCI, IF= 3.741, Top). 

[72] Ningbo Gao*, Kailun Chen, Cui Quan, Development of CaO-based adsorbents loaded on charcoal for CO2 capture at high temperature, Fuel, 2019. https://doi.org/10.1016/j.fuel.2019.116411 (SCI, IF= 5.578, Top). ESI高被引论文

[71] Yue Chai, Ningbo Gao*, Meihong Wang*, Chunfei Wu, H2 Production from Co-pyrolysis/gasification of Waste Plastics and Biomass under Novel Catalyst Ni-CaO-C, Chemical Engineering Journal, 2019.https://doi.org/10.1016/j.cej.2019.122947 (SCIIF= 10.652, Top).

[70] 王凤超高宁博*全翠废轮胎热解技术及炭黑产物的品质提升与应用研究进展[J]. 化工学报, 2019, 70(8): 2864-2875

[69] Ningbo Gao*, Zongyang Li, Cui Quan, Norbert Miskolczi, Attila Egedy, A new method combining hydrothermal carbonization and mechanical compression in-situ for sewage sludge dewatering: Bench-scale verification, Journal of Analytical and Applied Pyrolysis, 2019, 139: 187-195. https://doi.org/10.1016/j.jaap.2019.02.003. (SCIIF= 3.905, Top).

[68] Cui Quan, Ningbo Gao,* Huihui Wang, Hongman Sun, Chunfei Wu*,et al, Ethanol Steam Reforming on Ni/CaO catalysts for co-production of hydrogen and carbon nanotubes, International Journal of Energy Research, 2019, 43(3): 1255-1271. https://doi.org/10.1002/er.4365. (SCI, IF= 3.741, Top). 

 

[67] Ningbo Gao*, Lei Zhang and Chunfei Wu, Biomass and Wastes for Bioenergy: Thermochemical Conversion and Biotechnologies, BioMed Research International, 2018, 2018,1-2. (SCI, IF=2.583).

[66] Ningbo Gao*, Ying Han, Cui Quan, Study on Steam Reforming of Coal Tar over Ni-Co/ceramic Foam Catalyst for Hydrogen Production: Effect of Ni/Co Ratio, International Journal of Hydrogen Energy, 201843(49): 22170-22186. https://doi.org/10.1016/j.ijhydene.2018.10.119. (SCI, IF= 4.229, Top).

[65] Zhengzhao Ma, Jianghao Xie, Ningbo Gao*, Cui Quan, Pyrolysis behaviors of oilfield sludge based on Py-GC/MS and DAEM kinetics analysis, Journal of the Energy Institute, 2018, 92(4): 1053-1063. https://doi.org/10.1016/j.joei.2018.07.001 (SCI, IF=4.217).

[64] Chidiebere Diyoke, Ningbo Gao*, Mathew Aneke, Meihong Wang, Chunfei Wu, Modelling of down-draft gasification of biomass - an integrated pyrolysis, combustion and reduction process, Applied Thermal Engineering, 2018, 142, 444-456. https://doi.org/10.1016/j.applthermaleng.2018.06.079. (SCI, IF=3.771, Top) 

[63] Gao, Ningbo*, Quan Cui; Ma, Zhengzhao; Wu, Chunfei, Thermal characteristics of biomass pyrolysis oil and potential hydrogen production by catalytic steam reforming, Energy & Fuels, 2018, 32 (4): 5234–5243.Doi: 10.1021/acs.energyfuels.8b00365. (SCI, IF=3.091, Top) 

[62] Ningbo Gao*, Xiao Wang, Cui Quan, Chunfei Wu, Study of oily sludge pyrolysis combined with fine particle removal using a ceramic membrane in a fixed-bed reactor, Chemical Engineering & Processing: Process Intensification, 2018, 128: 276-281, (SCI, IF=2.234)

[61] Ayesha Tariq Sipra, Ningbo Gao*, Haris Sarwar, Municipal solid waste (MSW) pyrolysis for bio-fuel production: A review of effects of MSW components and catalysts, Fuel Processing Technology, 2018, 175:131-147. https://doi.org/10.1016/j.fuproc.2018.02.012. (SCI, IF=3.752, Top).

[60] Cui Quan, Zhengzhao Ma, Ningbo Gao*, Chi He. Pyrolysis and combustion characteristics of corncob hydrolysis residue. Journal of Analytical and Applied Pyrolysis, 2018,130: 72-78. https://doi.org/10.1016/j.jaap.2018.01.025. (SCI, IF=3.47, Top)

 

[59] Ningbo Gao*, Ying Han, Cui Quan, Chunfei Wu. Promoting hydrogen-rich syngas production from catalytic reforming of biomass pyrolysis oil on nanosized nickel-ceramic catalysts, Applied Thermal Engineering, 2017, 125, 297-305. (SCI/EI, IF=3.38, Top).

[58] 王笑,高宁博*,生物质气化重整技术的研究进展,生物质化学工程,2017, 51(2): 48-56.

[57] Ningbo Gao*, Cui Quan, Baoling Liu, Zongyang Li, et al. Continuous pyrolysis of sewage sludge in a screw-feeding reactor: products characterization and ecological risk assessment of heavy metals. Energy & Fuels, 2017, 31(5): 5063–5072. (SCI, IF=3.091, Top) 

[56] Liandong Zhu, Ningbo Gao, Rong-Gang Cong. Application of Biotechnology for the Production of Biomass-Based Fuels, BioMed Research International, vol. 2017, 2017. 1-2. (SCI, IF=2.14).

[55] Cui Quan, Ningbo Gao*, Chunfei Wu. Utilization of NiO/porous ceramic monolithic catalyst for upgrading biomass fuel gas. Journal of the Energy Institute. 2017, DOI: 10.1016/j.joei.2017.02.008.

[54] Cui Quan, Ningbo Gao*, Pyrolysis of biomass components in a TGA and a fixed-bed reactor: Thermochemical behaviors, kinetics, and product characterization J. Analy. Appl. Pyrolysis, 2016, 121, 84-92, SCI, IF=3.65.

[53] Cui Quan, Ningbo Gao*, Co-pyrolysis of biomass and coal: A review of effects of co-pyrolysis parameters, product properties and synergistic mechanisms, Biomed Research International, 2016, 2016, 6197867, SCI, IF=2.14.

[52] Ningbo Gao*, Xiao Wang, Aimin Li, Chunfei Wu, Zhifan Yin. Hydrogen production from catalytic steam reforming of benzene as tar model compound of biomass gasification, Fuel Processing Technology, 2016,148: 380-387.

[51] Shuo Cheng, Yuhua Wang, Ningbo Gao, Fumitake Takahashi, Aimin Li, Kunio Yoshikawa. Pyrolysis of oil sludge with oil sludge ash additive employing a stirred tank reactor, Journal of Analytical and Applied Pyrolysis, 2016, 120, 511-520.SCI, IF=3.65.

[50] Shuo Cheng, Fumitake Takahashi, Ningbo Gao, Kunio Yoshikawa, and Aimin Li, Evaluation of Oil Sludge Ash as a Solid Heat Carrier in the Pyrolysis Process of Oil Sludge for Oil Production, Energy Fuels, 201630 (7): 5970–5979. 

[49] Ningbo Gao*, Shuang Liu, Ying Han, Chen Xing, Aimin Li*,Steam reforming of biomass tar for hydrogen production over NiO/ceramic foam catalyst, International Journal of Hydrogen Energy, 2015, 40(25), 7983-7990. (SCI/EI, IF= 3.42)

[48] Gao, Ningbo*, Liu, Baoling, Li, Aimin, Li, Juanjuan, Continuous pyrolysis of pine sawdust at different reaction temperatures and solid residence times, Journal of Analytical and Applied Pyrolysis, 2015, 14, 155-162. (SCI/EI, IF2013= 3.070)

 

[47] Zhengzhao MaNingbo GaoLei XieAimin Li, Study of the fast pyrolysis of oilfield sludge with solid heat carrier in a rotary kiln for pyrolytic oil production, Journal of Analytical and Applied Pyrolysis, 2014,105:183-190 

[46] Ningbo Gao, Juanjuan Li, Benyu Qi, Aimin Li*, Yue Duan, Ze Wang, Thermal analysis and products distribution of dried sewage sludge pyrolysis. Journal of Analytical and Applied Pyrolysis, 2014, 105: 43-48. (SCI/EI, IF2013= 3.070)

[45] Ningbo Gao, Aimin Li*, Cui Quan, Lin Du, Yue Duan, TG-FTIR and Py-GC/MS analysis on pyrolysis and combustion of pine sawdust. Journal of Analytical and Applied Pyrolysis, 2013, 100: 26-32. (SCI/EI, IF2013= 3.070).

[44] Ningbo Gao, Aimin Li*, Liaoyuan Mao, Jiwen Yang, Drying Characteristics of the Furfural Residues of Biomass Hydrolyzation, Journal of Biobased Materials and Bioenergy, 2012. 6(6): 661-668. (SCI/EI, 影响因子1.037).

[43] Ningbo Gao, Aimin Li* and Cui Quan, Characteristics of hydrogen-rich gas production of biomass gasification with porous ceramic reforming, International Journal of Hydrogen Energy, 2012, 37(12): 9610–9618. (SCI, EI收录影响因子4.05). SCI: WOS:000305106300018.

[42] Ningbo Gao, Aimin Li* and Cui Quan, A novel reforming method for hydrogen production from biomass steam gasification, Bioresource Technology, 2009. 100(18): 4271-4277. (SCI, EI收录影响因子4.42).

[41] Ningbo Gao, Aimin Li* and Wanjing Li, Research into fine powder and large particle tyre pyrolysis. Waste Management & Research, 2009. 27(3): 242-250. (SCI, EI收录影响因子1.308).

[40] Ningbo Gao, Aimin Li*, Cui Quan and Fan Gao, Hydrogen-rich gas production from biomass steam gasification in an updraft fixed-bed gasifier combined with a porous ceramic reformer, International Journal of Hydrogen Energy, 2008, 33(20): 5430-5438. (SCI, EI收录影响因子2.73).

[39] Ningbo Gao and Aimin Li*, Modeling and simulation of combined pyrolysis and reduction zone for a downdraft biomass gasifier, Energy Conversion and Management, 2008, 49(12): 3483-3490, (SCI, EI收录影响因子1.18)

[28] Ningbo Gao and Aimin Li*, Emissions of SO2, NO and NO2 in biogas incinerator during solid waste gasification. Environmental Pollution and Public Health, Jun 14-16, 2009, (1-11): 6268-6271, Beijing. ISTPEI收录WOS:000286342803197

[27] Ningbo Gao, Aimin Li*, Proposal of A Semi-empirical Parameter Groups Model of Organic Solid Waste Gasification, The 12th Asian Pacific Confederation of Chemical Engineering Congress, Aug. 2008, Dalian, ISBN: 978-7-5611-4285-1.

[26] Ningbo Gao, Aimin Li*, Pollutants forming characteristics of typical solid waste gasification and combustion treatment, The 2nd China-Korea Joint Symposium on Incineration/Pyrolysis and Environmental Management, Mar, 28, 2006, Hangzhou, China.

[25] Ningbo Gao, Aimin Li*, Experimental study on solid waste gasification in fixed beds, 2nd International Conference on Cooling and Heating Technologies, July 26, 2006, Dalian, China, 260-268.

[24] Ningbo Gao, Aimin Li*, The characteristic parameters model on pyrolysis of solid waste, 1st Korea-China Joint Symposium on Incineration/Pyrolysis and Environmental Management, September 22, 2005, Seoul, Korea, 39-46.

[23] 高宁博,李爱民*,全翠.生物质高温气化重整制氢实验研究,太阳能学报,2014,35(5): 912-918.

[22] 高宁博李爱民*. 生物质气化及其影响因素研究进展,化工进展, 2010, 29:52-57.

[21] 高宁博, 李爱民*,蓄热式高温空气制备特性研究环境工程学报, 2009, 12(4): 2893-2896

[20] 高宁博李爱民*, 蓄热式高温水蒸汽制备实验研究,燃烧科学与技术,201117(2):170-174EI: 20112214017182

[19] 高宁博李爱民*, 固体废物气化处理半经验模型的研究太阳能学报, 2009, 30(8):1111-1117. (EI).

[18] 高宁博李爱民*, 有机废物气化焚烧时NOxSO2放的试验研究热力发电, 2008, 37(8): 21-25.

[17] 高宁博李爱民*, 有机废物在气化焚烧处理中尾气排放灰色预测模型大连理工大学学报, 2008, 48 (1): 33-38. (EI).

[16] 高宁博李爱民*, 蓄热式高温带压蒸气发生器检测与控制研究工业加热, 2008, 37(1): 23-25.

[15] 高宁博李爱民*, 蓄热式高温带压蒸气发生器设计环境工程学报, 2008, 10(2): 1433-1436.

[14] 高宁博李爱民*, 城市垃圾焚烧过程中主要污染物的生成和控制电站系统工程, 2006, 22(1): 38-40.

[12] 高宁博李爱民*, 李润东王志姜秀民基于VF的循环流化床热力计算通用程序设计热力发电, 2004, (1): 55-57.

[11] 高宁博李爱民*, 固体废弃物热解产物的参数群神经网络预测模型太阳能学报, 2003, 24(4): 523-526, (EI)