李丽凤

个人信息 研究领域 论文著作 荣誉奖励 招生信息 新建主栏目 基本信息（Basic Information） 名称 李丽凤，博士，能源科学与工程学院副教授。研究聚焦于太阳能热化学系统（高温）和光生物系统（室温）中的辐射传递、传热传质、化学反应动力学/细胞生长动力学以及耦合多物理场的数值模拟和实验研究。 Dr Lifeng Li is an associate professor at the School of Energy Science and Engineering. Her research interests lie in radiative transfer, transport phenomenon, chemical reaction kinetics/cell growth kinetics, and multi-physics simulations associated with solar thermochemical (high-temperature) and biochemical (room-temperature) systems. 个人学术主页（Personal Academic Profile）：Google Scholar; ORCID；ResearchGate 2024年9月入学硕士研究生还有名额，欢迎同学们联系：lifeng.li@hit.edu.cn 工作经历（Work Experience） 标题 工作单位 哈尔滨工业大学（Harbin Institute of Technology） 职位/职称 副教授（Associate Professor） 起讫时间 2023–至今（2023–Present） 简单介绍 帅永教授课题组（http://homepage.hit.edu.cn/shuaiyong） 标题 工作单位 新加坡国立大学（National University of Singapore） 职位/职称 博士后研究员（Research Fellow） 起讫时间 2021–2023 简单介绍 导师：Chi-Hwa Wang教授（https://blog.nus.edu.sg/chbewch/principle-investigator/）。期间主要从事对于用于微藻培育的光生物反应器的设计、模拟、优化及实验测试（This research focused on the design, modeling, optimization, and experimental testing of low-cost, modular photobioreactor systems for microalgae cultivation） 标题 工作单位 澳大利亚国立大学（The Australian National University） 职位/职称 研究员（Research Officer） 起讫时间 2020–2021 简单介绍 导师：Wojciech Lipiński教授（https://orcid.org/0000-0001-5478-6887），Joe Coventry副教授（https://cecc.anu.edu.au/people/joe-coventry）。研究课题为对于一种新型间接加热、固定床式的太阳能热化学反应器的实验测试。此反应器被用于实现基于碳酸钙煅烧–碳化循环的储能和碳捕集，反应所需热量由澳大利亚国立大学45千瓦电功率的太阳能模拟器提供。（This research focused on the experimental evaluation of an indirectly-irradiated, packed-bed solar thermochemical reactor for solar energy storage and carbon dioxide capture using calcination–carbonation chemical-looping cycling of calcium carbonate. The reactor prototype was investigated experimentally under simulated high-flux solar irradiation provided by the 45 kWe ANU high-flux solar simulator.） 教育经历（Education Background） 标题 博士（Doctor of Philosophy） 起讫时间 2015–2020 所学专业 太阳能光热利用与转换（Concentrating solar thermal technologies） 学习机构 澳大利亚国立大学（The Australian National University） 学历 简单介绍 导师：Wojciech Lipiński教授（https://orcid.org/0000-0001-5478-6887） 标题 科学硕士（Master of Science） 起讫时间 2012–2014 所学专业 能源技术（Energy Technolgies） 学习机构 德国卡尔斯鲁厄工业学院（Karlsruhe Institute of Technology）；瑞典乌普萨拉大学（Uppsala University） 学历 简单介绍 导师：Bjoern Laumert教授（https://www.kth.se/profile/laumert/），王武军研究员（https://www.kth.se/profile/wujun/） 标题 工学学士（Bachelor of Engineering） 起讫时间 2008–2012 所学专业 能源与环境系统工程（Energy and Environmental Systems Engineering） 学习机构 浙江大学（Zhejiang University） 学历 简单介绍 导师：俞自涛教授（https://person.zju.edu.cn/0005167），张良副教授（https://person.zju.edu.cn/solarthermal） 学术专著（Books and Book Chapters） 名称 学术专著章节（Book Chapters）: L. Li, B. Wang, R. Bader, T. Cooper, and W. Lipiński, 2021, Concentrating collector systems for high-temperature solar thermal and thermochemical applications, in: W. Lipiński (Ed.), Advances in Chemical Engineering, Elsevier, pp: 1–53, ISBN: 978-0-12-820647-8 (print) and 978-0-12-823183-8 (electronic), https://doi.org/10.1016/bs.ache.2021.10.001. X. Wang, F. Zhang, L. Li, H. Zhang, and S. Deng, 2021, Carbon dioxide capture, in: W. Lipiński (Ed.), Advances in Chemical Engineering, Elsevier, pp: 297–348, ISBN: 978-0-12-820647-8 (print) and 978-0-12-823183-8 (electronic), https://doi.org/10.1016/bs.ache.2021.10.005. 期刊论文（Journal Articles） 名称 Articles in Refereed Journals: 2023： L. Li1, A. Rahbari1, M. Taheri, R. Pottas, B. Wang, M. Hangi, L. Matthews, L. Yue, J. Zapata, P. Kreider, A. Bayon, C.-H. Wang, T.W. Simon, J. Coventry, and W. Lipiński*, 2023. Experimental evaluation of an indirectly-irradiated packed-bed solar thermochemical reactor for calcination–carbonation chemical looping. Chemical Engineering Journal 468, 143543, https://doi.org/10.1016/j.cej.2023.143543. L. Li, Z.M.H Mohd Shafie, T. Huang, R. Lau, and C.-H.Wang*, 2023. Multiphysics simulations of concentric-tube internal loop photobioreactors for microalgae cultivation. Chemical Engineering Journal 457, 141342, https://doi.org/10.1016/j.cej.2023.141342. 2022： L. Li, X. Xu, W. Wang, R. Lau, and C.-H. Wang*, 2022. Hydrodynamics and mass transfer of concentric-tube internal loop airlift reactors: A review. Bioresource Technology 359, 127451, https://doi.org/10.1016/j.biortech.2022.127451. J. Pottas1, L. Li1, M. Habib, C.-H.Wang, J. Coventry, and W. Lipiński*, 2022. Optical alignment and radiometry flux characterization of a multi-source high-flux solar simulator. Solar Energy 236, 434–444, https://doi.org/10.1016/j.solener.2022.02.026. 2021： S. Yang, L. Li, B. Wang, S. Li, J. Wang, P. Lund, and W. Lipiński*, 2021. Thermodynamic analysis of a conceptual fixed-bed solar thermochemical cavity receiver–reactor array for water splitting via ceria redox cycling. Frontiers in Energy Research 9, 253, https://doi.org/10.3389/fenrg.2021.565761. B. Wang, L. Li, F. Schaefer, J. Pottas, A. Kumar, V. M. Wheeler, and W. Lipiński*, 2021. Thermal reduction of iron–manganese oxide particles in a high-temperature packed-bed solar thermochemical reactor. Chemical Engineering Journal 410(C), 128255, https://doi.org/10.1016/j.cej.2020.128255. 2020： W. Lipiński*, E. Abbasi-Shavazi, J. Chen, J. Coventry, M. Hangi, S. Iyer, A. Kumar, L. Li, S. Li, J. Pye, J. F. Torres, B. Wang, Y. Wang, and V. Wheeler, 2020. Progress in heat transfer research for high-temperature solar thermal applications. Applied Thermal Engineering 184(C), 116137, https://doi.org/10.1016/j.applthermaleng.2020.116137. L. Li, B. Wang, J. Pye, R. Bader, W. Wang, and W. Lipiński*, 2020. Optical analysis of a multi-aperture solar central receiver system for high-temperature concentrating solar applications. Optics Express 28(25), 37654–37668, https://doi.org/10.1364/OE.404867. B. Wang, L. Li, R. Bader, J. Pottas, V. Wheeler, P. Kreider, and W. Lipiński*, 2020. Thermal model of a solar thermochemical reactor for metal oxide reduction. Journal of Solar Energy Engineering 142, 051002, https://doi.org/10.1115/1.4046229. L. Li, B. Wang, J. Pye, and W. Lipiński*, 2020. Temperature-based optical design, optimisation and economics of solar polar-field central receiver systems with an optional compound parabolic concentrator. Solar Energy 206, 1018–1032, https://doi.org/10.1016/j.solener.2020.05.088. L. Li, S. Yang, B. Wang, J. Pye, and W. Lipiński*, 2020. Optical analysis of a solar thermochemical system with a rotating tower reflector and a receiver–reactor array. Optics Express 28(13), 19429–19445, https://doi.org/10.1364/OE.389924. 2019： L. Li, B. Wang, R. Bader, J. Zapata, and W. Lipiński*, 2019. Reflective optics for redirecting convergent radiative beams in concentrating solar applications. Solar Energy 191, 707–718, https://doi.org/10.1016/j.solener.2019.08.077. L. Li, B. Wang, J. Pottas, and W. Lipiński*, 2019. Design of a compound parabolic concentrator for a multi-source high-flux solar simulator. Solar Energy 183, 805–811, https://doi.org/10.1016/j.solener.2019.03.017. 2016： W. Wang*, B. Wang, L. Li, B. Laumert, and S. Torsten, 2016. The effect of the cooling nozzle arrangement to the thermal performance of a solar impinging receiver. Solar Energy 131, 222–234, https://doi.org/10.1016/j.solener.2016.02.052. L. Li, J. Coventry, R. Bader, J. Pye, and W. Lipiński*, 2016. Optics of solar central receiver systems: A review. Optics Express 24(14), A985–A1007, https://doi.org/10.1364/OE.24.00A985. 毕业论文（Thesis Dissertations） 名称 博士毕业论文（Doctoral Thesis）: L. Li, 2021. Design, Modelling and Optimisation of Optical Systems for High-Temperature Concentrating Solar Applications, The Australian National University, https://doi.org/10.25911/245K-V846. 硕士毕业论文（Master Thesis）: L. Li, 2015. Numerical study of surface heat transfer enhancement in an impinging solar receiver. KTH Royal Institute of Technology, Uppsala University, Karlsruhe Institute of Technology, https://www.diva-portal.org/smash/record.jsf?pid=diva2:767646&dswid=-2762. 代表性会议论文及摘要（Selected Abstracts in Conference Proceedings） 名称 L. Li, X. Li and C.-H. Wang*. Multiphase reactors in solar-driven fuel and chemical production. In Proceedings of the Fluidization XVII conference, Edinburgh, Scotland, United Kingdom, 21–25 May, 2023. L. Li, Z.M.H. Mohd Shafie, T. Huang, R. Lau, and C.-H. Wang*. Multiphysics simulation of internal loop airlift photobioreactors for microalgae cultivation. In Proceedings of the 2022 AIChE Annual Meeting, Phoenix, 13–18 November 2022. L. Li, B. Wang, R. Bader, T. Cooper, and W. Lipiński*. Concentrating collector systems for high-temperature solar thermal applications. In Proceedings of the 2021 AIChE Solar Energy Systems Conference, virtual, 4–6 August 2021. L. Li, B. Wang, R. Bader, W. Wang, J. Pye and W. Lipiński*. Optical analysis of multi-aperture solar central receiver systems for high-temperature concentrating solar applications. In Proceedings of the 2020 SolarPACES International Symposium on Concentrating Solar Power and Chemical Energy, virtual, 29 September–2 October 2020. L. Li, B. Wang, J. Pottas, and W. Lipiński*. Application of a compound parabolic concentrator to a multi-source high-flux solar simulator. In Proceedings of the OSA 2018 Light, Energy and the Environment Congress, Sentosa Island, Singapore, 5–8 November 2018. Extended abstract. 研究领域（Research Area） 名称 研究聚焦于从高温热化学系统到室温光生物（微藻培育）系统，聚光比从1到3000的太阳能光热利用系统中的辐射模拟、光学设计及多物理场耦合传热传质强化。围绕聚光集热技术、反应器和热化学材料这三项关键技术开展系列创新性研究。研究涉及多学科交叉，主要有工程热物理（流动与传热强化、系统流体力学）、光学、辐射、化工机械（反应器设计、反应过程的热质传递）、材料科学、系统控制、化学反应动力学及细胞生长动力学。 太阳能驱动的热化学和微藻生物化学技术对比 Li et al., Chem. Eng. J. 457, 141342, 2023 Li et al., Bioresour. Technol. 359, 127451, 2022 其中，在高温热化学领域，致力于基于太阳能热化学循环的燃料制备、储能和碳捕集，运用数值和实验方法推动对热化学系统中涉及多尺度、多相流和多部件的多物理场过程的机理的理解。研究内容包括开发高密度、长周期的储热材料，提高光学系统效率，改进热化学反应器的设计，开展基于太阳能热化学多联产系统的集成和优化控制研究，提高系统经济性，降低对生态环境的影响等等。具体研究内容包括但不限于： · 太阳能聚光集热机理研究以及光学器件和系统的设计、模拟和优化 聚光太阳能应用中的光学器件和系统 Li et al., Adv. Chem. Eng. 058, 0001–0053, 2021 Li et al., Opt. Express 24(14), A985–A1007, 2016 Lipiński et al., Appl. Therm. Eng. 184, 116137, 2021 · 高温太阳能驱动的碳酸盐煅烧–碳化循环及其在碳中和和储能领域的应用 (c) 一种新型间接加热、固定床式太阳能反应器测试系统的（a）示意图和（b，c）照片，所需的高通量太阳能辐射由澳大利亚国立大学45 kWe太阳能模拟器（High-flux Solar Simulator）提供。 Li and Rahbari et al., Chem. Eng. J. 468, 143543, 2023 Reich et al., J. Sol. Energy Eng. 139(5), 054501, 2017 Pottas and Li et al., Sol. Energy 236, 434–444, 2022 · 高温太阳能驱动的基于金属氧化物热化学循环的燃料制备和储能 用于铁锰基氧化物还原测试的一种间接加热、固定床式太阳能反应器（内含自设计三维复合式抛物面聚光镜Compound Parabolic Concentrator, CPC）的设计示意图 Li et al., Sol. Energy 183, 805–811, 2019 Wang et al., Chem. Eng. J. 412, 128255, 2021 Fascinated by the fundamental aspects of solar-driven thermochemical processes, I am devoted to advancing the understanding of multi-physics processes involving multi-phase/multi-component media at multi-scales using experimental and numerical approaches. The development of solar-driven chemical systems relies on advances in optics, materials, reactions, and reactor design, as well as in multi-physics numerical modeling of complex thermochemical systems. The system techno-economics and environmental impacts are also to be explored. In particular, my research interests include： · Fundamental research on concentrating collectors and design, modeling and optimization of optical devices and systems; · High-temperature solar-driven carbonates-based calcination–carbonation cycling for carbon capture and energy storage; · High-temperature solar-driven metal oxides redox cycling for fuel production and energy storage. 荣誉奖励（Honors & Awards） 名称 2021, ANU Solar Thesis Prize (1 recipient per year), The Australian National University 2015–2020, ANU PhD Scholarship (international) and ANU University Research Scholarship (international), Australia 2012–2014, Education for Sustainable Energy Development (ESED) Scholarship (approximately 12 recipients per year globally), Canada 2012–2014, Full scholarship for master programme—Energy Technologies (ENTECH), from KIC InnoEnergy, European Institute of Innovation & Technology 招生信息（Perspective Students） 名称 本科招生：每年若干名，热爱学习，愿意钻研和从事科技创新实践活动。 硕士招生：每年1–2名，能积极主动学习，具有一定的创新思维。 欢迎感兴趣加入的同学联系并发送简历至lifeng.li@hit.edu.cn。 可选研究方向包括： 太阳能聚光器件和系统的光学设计和模拟 太阳能热化学反应器设计、模拟和实验 热化学反应材料动力学测试、分析和建模 太阳能热化学系统经济效益分析及生命周期评估 Undergraduate and graduate students who are interested in joining the group should send their CV to lifeng.li@hit.edu.cn. Perspective research topics include the following: Optical design, and modeling of solar concentrating devices and systems; Design, modeling, and experiments of solar thermochemical reactors; Experimental testing, evaluation, and modeling of the reaction kinetics of thermochemical materials; Techno-economic analyses and life cycle assessment of solar thermochemical systems.