基本信息
学历:博士
职称:教授(博导)
专业:
系别:天津大学环境学院环境工程系
电子邮箱:chunfeng.song@tju.edu.cn
电话:
通讯地址:天津市海河教育园区雅观路135号,天津大学北洋园校区43号楼B315室,300350
主要研究方向
1) 温室气体(CO2)捕集及资源化再利用
2) 环境微生物技术
3) 生物质能源
4) 过程模拟及优化
(详见课题组主页:http://catalysis.tju.edu.cn/)
教育及工作经历
2020.07–至今 天津大学,环境与工程学院,教授
2014.12–2020.06 天津大学,环境与工程学院,副研究员
2013.08–2014.11 日本东京大学,生产技术研究所,特任研究员
2013.09–2013.10 新加坡国立大学,访问学者
2010.08–2013.07 日本筑波大学,工学博士
2008.09–2010.07 中国农业大学,工学硕士
2004.10–2008.07 河北农业大学,工学学士
荣誉称号&获奖:
2020年 天津大学教工先锋岗
2020、2019、2018年(连续3年) 天津大学优秀硕士毕业论文指导教师
2020年 天津大学优秀本科毕业论文指导教师
2019年 天津大学优秀青年教师(首批)
2019年 沈志康奖教金
2019年 天津市教学基本功大赛(校内选拔赛),一等奖
2019年 全国大学生节能减排大赛,三等奖(指导教师)
2018年 天津市“青年人才托举工程”入选者(首批)
2018年 天津市创新人才推进计划入选者(第五批)
2018年 天津市131创新人才(第三层次)
2018年 天津大学青年文明岗
2018年 天津大学青年教师讲课大赛,一等奖/优秀课件奖
2018年 全国生命科学创新创业大赛,一等奖(指导教师)
2018年 全国大学生农业建筑环境与能源工程相关专业创新创业竞赛,二等奖(指导教师)
2018年 天津大学第二届“未来三十年”颠覆性创新创想大赛,一等奖(指导教师)
2017年 天津大学“北洋学者-青年骨干教师”
2016年 天津市海外高层次人才
学术及机构兼职:
天津市生物质能源环境国际联合研究中心,副主任
江苏泰兴经济开发区,(挂)副主任(2015)
天津市滨海新区环境局,(挂)副处长(2016)
天津市青年科技工作者学会,委员
教学经历
主讲课程:
《大气污染控制》——国家精品课程/一流本科课程/校级思政课程/校级虚拟仿真实验
《环境工程原理》——专业核心课/考研课程
《Air pollution control》(全英文)——校级精品全英文课程
《Practice and new technologies of air pollution control engineering》(全英文)
《环境保护与可持续发展》——校级通识课
《物理性污染控制》
在研项目
代表性科研项目:
[1] 国家重点研发计划—国际合作项目:CO2高效捕集及资源化关键技术,2019.10—2022.09,主持(首席科学家)
[2] 国家自然科学基金—面上项目:基于CO2“浓缩-凝华”机制的低能耗“膜分离-深冷”耦合沼气纯化机理及特性研究,2019.01—2022.12,主持
[3] 国家自然科学基金—青年项目:新型中空纤维膜渗透与低温相变复合的CO2捕集机理研究,2016.01—2018.12,主持
[4] 国家重点研发计划(子课题):微藻固碳系统与废水环境因子的交互作用机制,2016.07-2020.06,主持
[5] 国家科技重大专项:污泥高浓度厌氧消化及热能利用系统研究,2015.01-2018.12,项目骨干
[6] 天津市自然科学基金: 基于吸附热循环再生的Cu-Mn-Ce 负载型分子筛吸附分离VOCs机理,2017.04-2020.03,主持
[7] 横向项目:CO2捕集及资源化国际合作主题沙龙,2020.08-2020.11,主持
[8] 横向项目:二氧化碳吸收液开发合作,2019GFW-0192,2019.06-2019.12,主持
[9] 天津大学自主创新基金(战略布局-产学研培育):海洋微拟球藻多联产制备高值化学品关键技术,2019.01-2019.12,主持
[10]天津大学自主创新基金(攻坚预研-重点研发计划):挥发性有机硫化物高效催化技术及关键材料研究,2018.01-2018.12,主持
[11]天津大学自主创新基金(战略布局-产学研培育):基于“浓缩-相变”复合分离机制的沼气纯化技术研究,2017.01-2017.12,主持
[12]天津大学自主创新基金(人才团队-北洋骨干):CO2捕集及资源化再利用,2017.01-2018.12,主持
[13]天津大学自主创新基金(攻坚预研-重点研发计划):深冷相变CO2捕集耦合微生物再利用关键技术,2018.01-2018.12,主持
主要论文
代表性论文:
近5年在Renew. Sust. Energ. Rev., Environ. Sci. Technol., Appl. Energ., Chem. Eng. J., Bioresource Technol., Int. J. Green. Gas Con., Energ., Appl. Therm. Eng等环境、能源领域国际期刊,以第一/通讯作者发表SCI论文40余篇(ESI高被引2篇、热点论文1篇、封面论文4篇、邀稿论文1篇),授权专利8项,受邀作大会邀请报告2次。研究成果分别被中央电视台科教频道(CCTV-10)、人民日报、科技日报、天津日报、天津大学官网、天津大学科技网等媒体报道:
[1] C. Song,⁎, Q. Liu, S. Deng, H. Li, Y. Kitamura. Cryogenic-based CO2 capture technologies: State-of-the-art developments and current challenges.Renewable and Sustainable Energy Reviews101 (2019) 265–278(ESI高被引、热点论文)
[2] C. Song*, Q. Liu, N. Ji, S. Deng, J. Zhao, Y. Li, Y. Kitamura. Alternative pathways for efficient CO2 capture by hybrid processes—A review.Renewable and Sustainable Energy Reviews82 (2018) 215–231.(ESI高被引)
[3] S. Li, S. Zhao, S. Yan, Y. Qiu,C. Song *, Y. Li, Y. Kitamura. Food processing wastewater purification by microalgae cultivation associated with high value-added compounds production–a review,Chinese Journal of Chemical Engineering27 (2019) 2845–2856.(封面论文、邀稿)
[4] C. Song, Y. Kitamura*, S. Li, W. Jiang. Parametric Analysis of a Novel Cryogenic CO2Capture System Based on Stirling Coolers.Environmental Science & Technology46 (22) (2012) 12735-12741.
[5] C. Song*, Q. Liu, N. Ji, S. Deng, J. Zhao, Y. Kitamura. Natural gas purification by heat pump assisted MEA absorption process.Applied Energy204 (2017) 353–361.
[6] C. Song, Y. Kitamura*, S. Li. Evaluation of Stirling cooler system for cryogenic CO2capture.Applied Energy98 (2012) 491-501.
[7] C. Song *, Q. Liu, N. Ji, Y. Kansha, A. Tsutsumi. Optimization of steam methane reforming coupled with pressure swing adsorption hydrogen production process by heat integration.Applied Energy154 (2015) 392–401.
[8] C. Song*, Z. Fan, R. Li, Q. Liu, Y. Kitamura. Efficient biogas upgrading by a novel membrane-cryogenic hybrid process: Experiment and simulation study.Journal of Membrane Science565 (2018) 194-202.
[9] C. Song, Y. Qiu, M. Xie, J. Liu, Q. Liu, S. Li * L. Sun, K. Wang, Y. Kansha. Novel Regeneration and Utilization Concept Using Rich Chemical Absorption Solvent As a Carbon Source for Microalgae Biomass Production.Ind. Eng. Chem. Res.58 (2019) 11720−11727.(封面论文)
[10]C. Song, Y. Qiu, S. Li *, Z. Liu, G. Chen, L. Sun, K. Wang, Y. Kitamura. A novel concept of bicarbonate-carbon utilization via an absorption-microalgae hybrid process assisted with nutrient recycling from soybean wastewater.Journal of Cleaner Production237 (2019) 117864.
[11]C. Song *, G. Chen, N. Ji, Q. Liu, Y. Kansha, A. Tsutsumi. Biodiesel production process from microalgae oil by waste heat recovery and process integration.Bioresource Technology193 (2015) 192–199.(封面论文)
[12]C. Song⁎, J. Liu, Y. Qiu, M. Xie, J. Sun, Y. Qi, S. Li, Yutaka Kitamura. Bio-regeneration of different rich CO2absorption solvent via microalgae cultivation.Bioresource Technology290 (2019) 121781.
[13]C. Song*, Y. Wei, Y. Qiu, Y. Qi, Y. Li, Y. Kitamura. Biodegradability and mechanism of florfenicol via Chlorella sp. UTEX1602 and L38: Experimental study,Bioresource Technology272 (2019) 529–534.
[14]C. Song *, M. Mujahid, R. Li, S. Ahmad, Q. Liu, B. Zhang, et al. Pebax/MWCNTs-NH2mixed matrix membranes for enhanced CO2/N2separation.Greenh Gases Sci Technol10 (2020) 408–20.(封面论文)
[15]C. Song *, Y. Qiu, M. Xie, Y. Qi, S. Li, Y. Kitamura. Novel Bio-regeneration Concept via Using Rich Solution as Nutrition Resource for Microalgae Cultivation: Effect of pH and Feeding Modes.ACS Sustainable Chem. Eng.7 (2019) 14471−14478.
[16]C. Song *, M. Xie, Y. Qiu, Q. Liu, L. Sun, K. Wang, Y. Kansha. Integration of CO2absorption with biological transformation via using rich ammonia solution as a nutrient source for microalgae cultivation.Energy179 (2019) 618-627.
[17]C. Song⁎, Q. Liu, Y. Qi, G. Chen, Y. Song, Y. Kansha, Y. Kitamura. Absorption-microalgae hybrid CO2capture and biotransformation strategy—A review.International Journal of Greenhouse Gas Control88 (2019) 109–117.
[18]C. Song*, Q. Liu, N. Ji, S. Deng, J. Zhao, Y. Li, Y. Kitamura. Parametric study of a novel cryogenic-membrane hybrid system for efficient CO2separation.International Journal of Greenhouse Gas Control72 (2018) 74–81.
[19]C. Song *,Q. Liu, N. Ji, S. Deng, J. Zhao, Y. Li, Y. Kitamura. Reducing the energy consumption of membrane-cryogenic hybrid CO2 capture by process optimization.Energy124 (2017) 29–39.
[20]C. Song*,Q. Liu, N. Ji, S. Deng, J. Zhao, Y. Li, Y. Kitamura. Advanced cryogenic CO2 capture process based on Stirling coolers by heat integration.Applied Thermal Engineering114 (2017) 887–895.
[21]C. Song⁎, J. Liu, M. Xie, Y. Qiu, G. Chen, Y. Qi, Y. Kitamura. Intensification of a novel absorption-microalgae hybrid CO2utilization process via fed-batch mode optimization.International Journal of Greenhouse Gas Control82 (2019) 1–7.
[22]C. Song *, Q. Liu, N. Ji, S. Deng, J. Zhao, Y. Kitamura.Intensification of microalgae drying and oil extraction process by vapor recompression and heat integration.Bioresource Technology207 (2016) 67–75.
[23]C. Song *,Q. Liu, N. Ji, Y. Song, Y. Kitamura. Conceptual Design and Process Feasibility Analysis of a Novel Ammonia Synthesis Process by Efficient Heat Integration.ACS Sustainable Chemistry & Engineering5 (2017) 7420−7432.
[24]C. Song, Y. Kitamura*, S. Li, K. Ogasawara. Design of a cryogenic CO2capture system based on Stirling coolers.International Journal of Greenhouse Gas Control7 (2012) 107-114.
[25]C. Song, Y. Kitamura*, S. Li, W. Jiang. Analysis of CO2frost formation properties in cryogenic capture process.International Journal of Greenhouse Gas Control13 (2013) 26-33.
[26]C. Song*, Y. Kitamura, S. Li. Energy analysis of the cryogenic CO2capture process based on Stirling coolers.Energy65 (2014) 580-589.
[27]C. Song, Y. Kitamura *, S. Li, J. Lu. Deposition CO2Capture Process Using a Free Piston Stirling Cooler.Industrial & Engineering Chemistry Research52 (42) (2013) 14936–14943.
[28]C. Song*, J. Lu, Y. Kitamura. Study on the COP of free piston Stirling cooler (FPSC) in the anti-sublimation CO2capture process.Renewable Energy74 (2015) 948–954.
[29]X. Hu,C. Song *, H. Mu, Z. Liu, Kitamura Y. Optimization of simultaneous soybean processing wastewater treatment and flue gas CO2fixation via chlorella sp. L166 cultivation.Journal of Environmental Chemical Engineering8 (2020) 103960.
[30]C. Song *, X. Han, Y. Qiu, Z. Liu, S. Li, Y. Kitamura. Microalgae carbon fixation integrated with organic matters recycling from soybean wastewater: Effect of pH on the performance of hybrid system.Chemosphere248 (2020) 126094.
[31]C. Song *, Z. Liu, C. Wang, S. Li, Y. Kitamura. Different interaction performance between microplastics and microalgae: The bio-elimination potential of Chlorella sp. L38 andPhaeodactylum tricornutum MASCC-0025.Science of the Total Environment723 (2020) 138146.
[32]C. Song *, X. Hu, Z. Liu, S. Li, Y. Kitamura. Combination of brewery wastewater purification and CO2fixation with potential value-added ingredients production via different microalgae strains cultivation.Journal of Cleaner Production268 (2020) 122332.
[33]C. Song *, R. Li, Z. Fan, Q. Liu, B. Zhang, Y. Kitamura. CO2/N2separation performance of Pebax/MIL-101 and Pebax /NH2-MIL-101 mixed matrix membranes and intensification via sub-ambient operation.Separation and Purification Technology238 (2020) 116500.
主办国际会议及报告:
[1] 碳捕集及资源化国际科技交流与合作主题沙龙(大会主席),天津,2020.10
[2] 1st International Workshop of CO2Capture and Utilization(大会主席),天津,2019.12
[3] 中日水处理与回用前沿技术论坛(大会主席),2018.06
[4] 第一届有色金属冶炼烟气多污染物高效净化与资源化利用技术研讨会,昆明,2020.12(邀请报告)
[5] 第二十四届大气污染防治技术研讨会,北京,2020.10(邀请报告)
[6] 4th International Symposium on Environmental Science and Technology,Hangzhou,China,2019.10(邀请报告)
[7] 中低温热能高效利用教育部重点实验室2018-2019 年度学术委员会年会,天津,2019.12(邀请报告)
[8] CO2捕集封存与制高价值化学品论坛,南京,2018.11(邀请报告)
[9] ”A novel desublimation CO2capture process based on Free Piston Stirling Cooler (FPSC) system”, International Conference on Greenhouse Gas Technologies (GHGT-11), Kyoto, Japan. 2012.11
[10]”Application of Free Piston Stirling Cooler (SC) on CO2Capture Process”, International Conference on Applied Energy (ICAE-2012), Suzhou, China. 2012.7
[11]”Design of a low-cost CO2capture process based on heat integration technology” The 6th International Conference on Applied Energy–ICAE2014, Taipei, Taiwan, 2014.5
[12]”Improving net efficiency of power plants with CO2capture units using self-heat recuperation technology” The 21th International Congress of Chemical and Process Engineering CHISA 2014, Prague, Czech Republic, 2014.8
[13]”Energy saving CO2capture process by effective reaction and evaporation heat recuperation―A parametric study” The 4th Asian Conference on Innovative Energy & Environmental Chemical Engineering, Yeosu, Korea, 2014.11
主要授权国家专利:
[1] 宋春风、孙亚伟、刘庆岭、纪娜。低温CO2分离装置,授权号:ZL201610875761.0
[2] 宋春风、孙亚伟、刘庆岭、纪娜。一种膜渗透与低温相变复合的二氧化碳捕集装置,授权号:ZL201720290916.4
[3] 宋春风、谢美连、孙亚伟、刘庆岭、纪娜。蒸汽再压缩与热量交换集成的微藻干燥系统,授权号:ZL201720611766.2
[4] 宋春风、孙亚伟、刘庆岭、纪娜。一种新型的低温膜分离装置及测试方法,授权号:ZL201610851276X
[5] 宋春风、谢美连、孙亚伟、刘庆岭、纪娜。基于蒸汽再压缩与热量交换集成的微藻联合处理装置,授权号:ZL201720615643.6
[6] 宋春风、谢美连、孙亚伟、刘庆岭、纪娜。基于蒸汽再压缩与热量交换集成的微藻油脂萃取系统,授权号:ZL201720611763.9
欢迎各位有志青年访问、加盟 “大气环境与生物能源课题组”!
(课题组主页:http://catalysis.tju.edu.cn/)