韩龙

   韩龙，教授、博士生导师，现任全省清洁能源转化与利用重点实验室副主任,浙工大生态工业创新研究院副院长。博士毕业于浙江大学能源清洁利用国家重点实验室，曾在清华大学/中国能源建设集团广东省电力设计研究院进行博士后研究，是国家留学基金委公派美国普渡大学访问学者，曾挂职科技部资源配置与管理司工作。现为中国可再生能源学会专家委员，中国化工学会工程热化学专委会委员，中国环境科学学会环境与热能利用专委会委员，浙江省能源研究会理事，浙江省可持续发展研究会会员，杭州市能源学会碳中和专业委员会秘书长。担任科技部碳捕集技术咨询专家、国家自然科学基金、广东等省科技项目评审专家、浙江省科技厅碳达峰碳中和科技创新行动方案编制专班核心成员、浙江省碳中和白皮书编制专家组成员、浙江省发展改革委节能评审专家，担任10多个SCI期刊审稿人。作为项目负责人主持国家自然科学基金青年项目、面上项目、国家重点研发计划任务课题、浙江省“尖兵”“领雁”重点研发计划项目、浙江省科技厅公益技术项目等课题的研究，产学研成绩显著，入选中国颗粒学会流态化专委会托举青年人才、浙江省能源科技优秀工作者、浙江工业大学高层次人才培养计划。发表SCI论文50余篇，撰写中英文著作4部（章），授权专利10余件，代表成果获得清华大学、中国工程院、美国哥伦比亚大学、英国伦敦帝国理工学院、日本东京大学等著名机构和学者的积极评价。

本科生课程：热工基础；节能原理；能源与环境专业前沿进展

研究生课程：氢能与碳捕集技术；能源系统分析与系统节能

2022年浙江工业大学机械工程学院科技竞赛二等奖（李庆刚）。

2021年浙江工业大学节能减排社会实践与科技竞赛二等奖（郭会等）；

2021年浙江工业大学节能减排社会实践与科技竞赛三等奖（乌悦伦等）；

2020年度浙江工业大学本科生优秀毕业论文（王立凡）；

2020年度免试推荐保送山东大学研究生（贾爱光）；

2020年度免税推荐保送浙江工业大学研究生（乌悦伦）；

2020年度浙江工业大学优秀毕业研究生（刘琦）；

2019年度免试推荐保送浙江工业大学研究生（巫平江）；

2017年度街能创始人兼CEO（班主任）；

2016年度浙江工业大学优秀班集体（班主任）

1 国家自然科学基金青年项目：钙铝石负载钙铁氧化物协同强化焦油重整与抑制积碳机理，主持

2 国家自然科学基金面上项目：基于氧化铁/氧化钙-钙铝石多功能材料组分协同作用强化循环过程焦油脱除和CO2捕集的制氢机理，主持

3 国家重点研发计划项目子课题：新型高活性低成本中温CO2固体吸附材料的规模化制备技术，主持 

4 国家重点研发计划项目子课题： 化学链气化过程中的硫氮污染物控制，主持

5 国家重点研发计划项目子课题：纤维素/半纤维素定向解聚制备糖平台分子的反应机理，主持

6 浙江省科技厅“尖兵”“领雁”重点研发计划“双碳”专项项目：竹生物质资源化能源化炭气联产技术研发与示范应用，主持

7 浙江省科技厅公益技术项目：生物质吸收体气化中新型复合钙基吸收剂开发及关键技术研究，主持

8 清华大学电力系统国家重点实验室开放基金：新型钙基吸收剂强化生物质焦油重整与积碳抑制机理，主持

9 浙江大学能源清洁利用国家重点实验室开放基金：新型钙基复合吸收剂强化生物质焦油重整研究，主持

10 41T/H生物质循环流化床锅炉优化改造，企业委托横向课题，主持

发表论文50余篇，合作撰写中英文著作4部（章），作为首席作者之一参编《第四次气候变化国家评估报告》特别报告—《中国碳捕集利用与封存技术评估报告》，授权专利10余件。近年的部分成果如下：

(1) Enhanced thermochemical energy storage properties of SiC-doped calcium-based material with steam addition during heat charging process, Journal of Energy Storage 95 (2024) 112609.

(2) Experimental and numerical investigation of chemical-loop steam methane reforming on monolithic BaCoO₃/CeO₂ oxygen, Energy302 (2024) 131896.

(3) Fluidized bed chemical looping gasification of sewage sludge with bituminous coal to produce H₂ rich syngas: An examination on fuel synergy and reaction conditions. Journal of the Energy Institute, 2023, 111: 101442.

(4) Enhanced Sewage Sludge Gasification by Bauxite-Modified Carbide Slag for Hydrogen-Rich Syngas Production with In Situ CO₂ Capture, Energy Technology, 2023, 11 (9), 202300071.

(5) Energy and exergy analyses of biomass IGCC power plant using calcium looping gasification with in situ CO₂ capture and negative carbon emission. Biomass Conversion and Biorefinery. 2023.

(6) Optimizing the gasification performance of biomass chemical looping gasification: enhancing syngas quality and tar reduction through red mud oxygen carrier. Biomass Conversion and Biorefinery. 2023.

(7) Conversion of glucose into 5-hydroxymethylfurfural by carbonaceous solid acid catalysts loaded with Brønsted acid and Lewis acid in biphasic system, Research on Chemical Intermediates, 2023, 49 (10): 4523-4539.

(8) Biomass calcium looping gasification via cement-modified carbide slag in fluidized bed: an examination on enhanced multi-cycle CO₂ capture and hydrogen production. Biomass Conversion and Biorefinery. 2023.

(9) Synthesis of a composite Fe-CaO-based sorbent/catalyst by mechanical mixing for CO₂ capture and H₂ production: An examination on CaO carbonation and tar reforming performance, Journal of the Energy Institute, 2023, 109: 101256.

(10) Enhanced multi-cycle CO₂ capture and tar reforming via a hybrid CaO-based absorbent/catalyst: effects of preparation, reaction conditions and application for hydrogen production, International Journal of Hydrogen Energy, 2023, 48, 27: 9988-10001.

(11) Syngas production from chemical-looping steam methane reforming: the effect of channel geometry on BaCoO₃/CeO₂ monolithic oxygen carriers，Energy, 2023, 263, 126000.

(12) 水蒸气强化纤维素模板改性钙基吸附剂固碳性能及强度，化工进展，2023，42 (6): 3217-3225.

(13) Techno-Economic analysis of hydrogen and electricity production by biomass calcium looping gasification, 2022, 14 (4): 2189.

(14) Techno-Economic Analysis of Hydrogen and Electricity Production by Biomass Calcium Looping Gasification，Sustainability, 2022, 14 (4): 2189.

(15) Effect of steam addition during calcination on CO₂ capture performance and strength of bio-templated Ca-based pellets. Journal of CO₂ Utilization, 2022, 63, 102127.

(16) Hydrothermal co-liquefaction of rice straw and Nannochloropsis: The interaction effect on mechanism, product distribution and composition. Journal of Analytical and Applied Pyrolysis, 2022, 161, 105368.

(17) Hydrothermal co-liquefaction of rice straw and waste cooking-oil model compound for bio-crude production. Journal of Analytical and Applied Pyrolysis, 2021, 160, 105360.

(18) Thermodynamic analysis of 350 MWe coal power plant based on calcium looping gasification with combined cycle, International Journal of Greenhouse Gas Control, 2021, 110 (103439): 1-11.

(19) Steam Reactivation of Biotemplated CaO-Based Pellets for Cyclic CO₂ Capture, Energy & Fuels, 2021, 35 (7): 6056-6067.

(20) Promoted calcium looping H₂ production via catalytic reforming of polycyclic aromatic hydrocarbon using a synthesized CO₂ absorbent prepared by impregnation, International Journal of Energy Research, 2021, 45 (7): 10409-10424.

(21) 烟煤氧解耦化学链气化及氮氧化物生成机理，燃烧科学与技术，2021, 27 (5): 569-579.

(22) Enhanced hydrogen production via catalytic tar reforming with in situ carbon dioxide capture: Effects of a hybrid iron-calcium absorbent prepared by impregnation. Energy Conversion and Management., 2020, 214 (112834): 1-13.

(23) Catalytic toluene reforming with in-situ CO₂ capture via an iron-calcium hybrid absorbent for promoted hydrogen production, Energy Technology, 2020, 8 (6): 2000083.

(24) A novel hybrid iron-calcium catalyst/absorbent for enhanced hydrogen production via catalytic tar reforming with in-situ CO₂ capture, International Journal of Hydrogen Energy, 2020, 45: 10709-10723.

(25) 赤铁矿作用下煤化学链气化过程碳氮元素转化机理，石油学报（石油加工），2020, 36 (6): 1151-1161.

(26) Simulation and optimization of ion transfer membrane air separation unit in an IGCC power plant, Applied Thermal Engineering, 2018, 129: 1478-1487.

(27) Influences of syngas pretreatment on the performance and energy distribution in an IGCC power plant, Chemical Engineering Research and Design, 2018, 131: 117-126.

(28) 新型钙基吸收剂捕集CO₂和脱除焦油研究，动力工程学报，2018, 38 (7): 578-586.

(29) Developing a novel CaO-based sorbent for promoted CO₂ capture and tar reduction, Energy & Fuels, 2017, 31 (5): 5306-5317.

(30) Integration optimisation of elevated pressure air separation unit with gas turbine in an IGCC power plant, Applied Thermal Engineering, 2017, 110: 1525-1532.

(31) Influences of syngas sensible heat recovery on performance of IGCC power plant based on coal water slurry gasification. Journal of Chinese Society of Power Engineering, 2014, 34 (12): 79-84. (in Chinese）

(32) H₂ rich gas production via pressurized fluidized bed gasification of sawdust with in situ CO₂ capture, Applied Energy, 2013, 109: 36-43.

(33) Performance improvement of IGCC power station by preheating the clean syngas, Thermal Power Generation, 2013, 42 (10): 39-53. (in Chinese）

(34) Hydrogen production via CaO sorption enhanced anaerobic gasification of sawdust in a bubbling fluidized bed, International Journal of Hydrogen Energy, 2011, 36 (8): 4820-4829.

(35) TG-FTIR study on pyrolysis of wheat-straw with abundant CaO additives, Spectroscopy and Spectral Analysis, 2011, 31 (4): 942-946. (in Chinese)

(36) Influence of CaO additives on wheat-straw pyrolysis as determined by TG-FTIR analysis, Journal of Analytical and Applied Pyrolysis, 2010, 88 (2): 199-206.

(37) Hydration reactivation of CaO-based sorbent for cyclic calcination-carbonation reactions, Proceedings of the 20th International Conference on Fluidized Bed Combustion, 2009.

38) 王涛，秦昌雷，韩龙，李超。2021，《第四次气候变化国家评估报告》特别报告—《中国碳捕集利用与封存技术评

估报告》第二章《CO2捕集技术》，科学出版社。

39) 韩龙，王勤辉，马强，余春江，骆仲泱，岑可法。2009，加压条件下CaO碳酸化反应动力学研究，中国电机工程学报，29 (14): 41-46。(EI，入选中科院卓越计划期刊)

40) 韩龙，张媛，林康等，一种增强化学链气化制氢过程焦油脱除与CO2捕集的方法，授权号ZL 201610758084.4

   （发明专利）。

41) 韩龙，邓广义，范永春等，用于改进IGCC发电设施性能的预热清洁合成气方法及系统，授权号ZL 201310348123.X   （发明专利）。