老王论坛

个人简介：尹华意，男，1984年生，老王论坛 教授，博士生导师，环境工程系主任，湖北省资源与能源可持续发展国际合作基地副主任。2017年入选国家海外高层次青年人才计划。2007获湖北师范大学化学学士学位，2012年获老王论坛 环境科学博士学位（导师：汪的华教授），2012-2017在美国麻省理工学院（导师：Donald R. Sadoway教授）和德州大学奥斯汀分校（导师：Allen J. Bard教授）从事博士后研究，2017-2022任东北大学冶金学院教授，2022加入老王论坛 资环院。主要从事“金属-能源-环境-可持续发展”方面的研究，以新能源产业链中的首端矿产资源和尾端退役器件及副产物（退役锂电池、光伏组件、风机叶片、高温合金、废盐、CO₂等）为对象，解决产业链中的资源短缺、环境污染重和碳排放高的问题，具体包括：1）新能源资源循环与智能监测，2）能源金属绿色提取与污染控制，3）电解技术-人工智能-可持续发展。先后主持国家自然科学基金青年、面上、原创探索项目及多项企业横向课题，近年相关成果以第一或通讯作者在Nature Sustain、Nature Energy、Nature Commun、PNAS、Energy & Environmental Science、ES&T、Angew、科学通报、电化学等杂志上发表论文200余篇，参与撰写英文专著两个章节，授权国家发明专利10余件（5项实现转化），获湖北省自然科学一等奖（排名第2）、美国TMS“提取冶金青年领袖奖”、中表镀优秀教师奖、邱定蕃有色冶金青年科提名技奖。担任稀有金属青年编委、Separation Science & Technology 特邀编委、中国腐蚀与防护学报编委、中国腐蚀与防护学会青年工作委员会副主任、中国再生资源战略联盟委员、中国有色金属协会冶金物理化学专业委员会委员。

ResearchGate: //www.researchgate.net/profile/Huayi-Yin-2

ORCid: //orcid.org/0000-0003-1765-496X

Curriculum Vitae：Huayi Yin is a professor at the School of Resource and Environmental Science (SRES), Wuhan University (WHU), Wuhan, China. His research interests focus on “metal-energy-environment-sustainability” nexus. In order to solve the challenges of resource scarcity, heavy pollution and high carbon emissions, his group studies the efficient extraction of critical metals from minerals and recycling/upcycling of end-of-life Li-ion batteries, solar panels, wind turbines, super alloys, waste salts, CO₂, etc. The results of his research aim to support the sustainable development of the renewable energy supply chain and achieve a net-zero society. The research can be divided into three categories: 1) Resource recycling and intelligent monitoring of renewable energy waste, 2) Green extraction of energy metals and pollution control, and 3) Electrolysis Technology-Artificial Intelligence-Sustainability.

He received BS in Chemistry from Hubei Normal University in 2007, PhD in Environmental Science in 2012 from the Wuhan University, China, worked as a postdoctoral associate in Professor Donald R. Sadoway’s group at Massachusetts Institute of Technology (MIT) and in Professor Allen J. Bard’s group at The University of Texas at Austin (UT-Austin), and became a professor at the School of Metallurgy in Northeastern University (NEU), Shenyang, China. He joined the SRES faculty at WHU in 2022.

2022之后的代表性论文 (representative articles after 2022)

1. Gao SB, Chen X, Qu JK, Guo YY, Shi H, Pang FZ, Guo L, Qu X, Wang DH* & Yin HY*, Recycling of Silicon Solar Panels through a Salt-Etching Approach, Nature Sustainability, 2024, 7(7), 920–930.

2. Qiu BL, Liu MJ, Qu X, Zhou FY, Xie HW, Wang DH, Lee L Y S* & Yin HY*, Waste Plastics Upcycled for High-Efficiency H₂O₂ Production and Lithium Recovery via Ni-Co/Carbon Nanotubes Composites, Nature Communications, 2024, 15(1), 6473.

3. Du KF, Gao EL, Zhang CB, Ma YS, Wang PL, Yu R, Li WM, Zheng KY, Cheng XH, Tang DY, Deng BW, Yin HY* & Wang DH*, An Iron-Base Oxygen-Evolution Electrode for High-Temperature Electrolyzers, Nature Communications, 2023, 14(1), 253.

4. Liu W, Wang XT, Wang F, Du KF, Zhang ZF, Guo YZ*, Yin HY* & Wang DH*, A Durable and pH-Universal Self-Standing MoC–Mo₂C Heterojunction Electrode for Efficient Hydrogen Evolution Reaction, Nature Communications, 2021, 12(1), 6776.

5. Qu JK, Chen X, Xie HW, Gao SB, Wang DH & Yin HY*, Anode Electrolysis of Sulfides, Proceedings of the National Academy of Sciences of the United States of America, 2022, 119(31),1-7.

6. Cai MY, Wang SY, Wang HY, Zhou FY, Tang MY, Zhang XD, Qu X, Wang DF, Wang DH, Yin HY*, A Low-Carbon Space-Isolated Zinc Hydrolysis for Harvesting Hydrogen and Salts from Seawater and Wastewater, Angewandte Chemie International Edition, 2025: e12441.

7. Cai MY, Shi H, Zhang Y, Qu JK, Wang HY, Guo YY, Du KF, Li W, Deng BW, Wang DH, Yin HY*, Rechargeable Zn-H₂O Hydrolysis Battery for Hydrogen Storage and Production, Angewandte Chemie International Edition, 2024, 163(26), e202404025.

8. Zhao JJ, Zhou FY, Wang HY, Qu X, Wang DF, Cai YQ, Zheng ZY, Wang DH & Yin HY*, Coupling Electrochemical Leaching with Solvent Extraction for Recycling Spent Lithium-Ion Batteries, Environmental Science & Technology, 2024, 58(38), 16803-16814.

9. Zhou FY, Wang HY, Wang SY, Zhao JJ, Qu X, Wang DF, Cai YQ, Zheng ZY, Wang DH & Yin HY*, Balancing the Components of Biomass and the Reactivity of Pyrolysis Gas: Biomass-Assisted Recycling of Spent LiCoO₂ Batteries, Environmental Science & Technology, 2024, 58(4), 2102–2111.

10. Qiu BL, Liu MJ, Qu X, Zhang BL, Xie HW, Wang DH, Lee L Y S & Yin HY*, Recycling Spent Lithium-Ion Batteries Using Waste Benzene-Containing Plastics: Synergetic Thermal Reduction and Benzene Decomposition, Environmental Science & Technology, 2023, 57(19), 7599–7611.

2018年之前代表性论文：(representative articles Prior to 2018)

1. Yin HY, Chung B, Chen F, Ouchi T, Zhao J, Tanaka, Sadoway DR.*, Faradaically selective membrane for liquid metal displacement batteries, Nature Energy, 2018, 3, 127-131.

2. Yin, HY; Chung, B.; Sadoway, DR.* Electrolysis of a molten semiconductor. Nature Communications 2016, 7 (1), 12584.

3. Li HM, Yin HY^#, Wang KL, Chen SJ, Jiang K*, & Sadoway D R, Liquid metal electrodes for energy storage batteries, Advanced Energy Materials, 2016, 6, 201600483.

4. Zhao, J, Yin, HY^#, Lim, TH, Xie, HW, Hsu, HY, Forouzan, F, Bard, AJ*, Electrodeposition of Photoactive Silicon Films for Low-Cost Solar Cells, Journal of the Electrochemical Society, 2016, 163, D506-D514.

5. Yin HY, Xiao W, Mao XH, Zhu H & Wang DH*, Preparation of a porous nanostructured germanium from GeO₂ via a "reduction-alloying-dealloying" approach, Journal of Materials Chemistry A, 2015, 3, 1427-1430.

6. Yin HY, Lu BH, Xu Y, Tang DY, Mao XH, Xiao W & Wang DH*, Harvesting Capacitive Carbon by Carbonization of Waste Biomass in Molten Salts, Environmental Science & Technology, 2014, 48, 8101-8108.

7. Yin HY, Mao XH, Tang DY, XiaoW, Xing LR, Zhu H, Wang DH* & Sadoway DR., Capture and electrochemical conversion of CO₂ to value-added carbon and oxygen by molten salt electrolysis, Energy & Environmental Science, 2013, 6, 1538-1545.

8. Yin HY, Xiao W, Mao XH, Wei WF, Zhu H & Wang DH*, Template-free electrosynthesis of crystalline germanium nanowires from solid germanium oxide in molten CaCl₂-NaCl, Eletrochimica Acta, 2013, 369-374.

9. Yin HY, Tang DY, Zhu H, Zhang Y & Wang DH*, Production of iron and oxygen in molten K₂CO₃-Na₂CO₃ by electrochemically splitting Fe₂O₃ using a cost affordable inert anode, Electrochemical Communications, 2011, 13(12):1521-1524

10. Yin HY; Gao LL, Zhu H, Gan FX & Wang DH*, On the development of metallic inert anode for molten CaCl₂-CaO system, Electrochimica Acta, 2011, 56(9): 3296-3302

专利：

1. 名称:一种回收再利用废旧晶硅太阳能板的方法 （ZL202210206141.3）

2. 名称:一种乙醇为还原剂湿法回收废锂电池中 Co 和 Li 的方法（ZL201910084974.5）

3. 名称:一种利用醇-水蒸汽回收废旧锂电池正极材料中金属元素的方法（ZL 202210187189.4）

4. 名称:一种熔盐辅助碳热还原回收锂电池正极材料的方法（ZL201910085003.2）

5. 名称:一种熔盐电解回收废旧钴酸锂电池中钴和锂的方法（ZL201910085004.7）

6. 名称:一种亚临界水中铵盐辅助的高选择性回收废旧锂离子电池正极材料的方法(202210189347.X)

7. 名称：一种无氯气排放电解制备碱金属和碱土金属的方法(ZL202210862344.8)

8. 名称：一种熔盐电化学插层法制备二位层状 MoS2 材料的方法（ZL201910085008.5）

9. 名称：基于切割硅废料的纳米硅和硅碳复合及制法和应用（ZL2019100560085.1）

10. 名称：一种水溶液电解固态金属硫化物制备金属的方法(ZL201810410693.X)

11. 名称：基于熔盐利用煤制备超级电容器用活性碳粉的方法（ZL2008 1 1154270.2）

12. 名称：利用无锂钙基熔盐法处理冶金废气并资源化利用的方法（ZL201910085216.5）

13. 名称：一种制备锂离子电池硅-碳负极材料的方法(ZL201810410263.8)

14. 名称：一种熔盐电化学辅助金属焊接的方法（ZL201910085217.X）

15. 名称：一种熔盐电化学法对不锈钢表面渗氮或者碳氮共渗的方法（ZL201910085005.1）

16. 名称：一种熔盐辅助碳热还原回收锂离子电池正极材料的方法（ZL201910085003.2）

17. 名称：：一种电化学辅助粉末治金制备多孔钛或钛合金的方法（ZL201810410265.7）

18. 名称：一种熔盐溶剂化法制备纳米Cu2O颗粒的方法（ZL 201811106493.1）

19. 名称：一种从铜矿中直接风力铜并制备Cu2O功能材料的方法（ZL201910560111.0）

20. 名称：一种电化学辅助粉末冶金制备多孔钛或者钛合金的方法（ZL201810410265.7）

承担的项目：

1. 国家自然科学基金原创项目：原位逆向电解驱动退役锂电池材料结构解离与高值化利用（52554011），2026-01-01至2028-12-31，主持。

2. 国家自然科学基金面上项目：硫化物阳极电解冶金新技术基础研究（52374308），2024-01-01至2027-12-31，主持。

3. 国家自然科学基金青年项目：硫化物全液态电解制备锑及锑-铅合金研究（51704060），2018-01-01至2020-12-31，主持。

4. 国家自然科学基金联系重点项目：火星大气环境二氧化碳高温原位能源转换与存储机制研究（U22B2071），2023年1月至2026年12月，参与。

教育经历：

2003.09-2007.06 湖北师范大学 本 科

2007.09-2012.06 武 汉 大 学 博 士 (导师：汪的华)

工作经历：

2012.07-2013.10 麻省理工学院 博士后 （合作导师：Donald R. Sadoway）

2013.11-2014.10 德州大学奥斯汀分校 博士后 (合作导师：Allen J. Bard)

2014.11-2017.06 麻省理工学院 博士后 （合作导师：Donald. R Sadoway）

2017.07-2022.08 东北大学 教 授

2022.08 - 今 老王论坛 教 授

研究方向：

1) 新能源资源循环与智能监测

2) 能源金属绿色提取与污染控制

3) 电解技术-人工智能-可持续发展

Research interests:

1) Resource recycling and intelligent monitoring of renewable energy waste

2) Green extraction of energy metals and pollution control

3) Electrolysis technology-artificial intelligence-sustainability

一、 能源资源循环与智能监测

针对退役新能源器件中资源利用不足和环境污染问题，开展退役锂离子电池、铅酸电池、光伏组件、风机叶片、功能合金等固废智能监测、有价资源提取和污染控制方面的研究，研究退役能源器件的智能识别与监测技术（如遥感和图像识别、光谱监测技术等）和绿色回收技术，获得新能源器件典型光谱特征和复杂元素的赋存状态和结构特征，建立复杂元素富集和分离过程中的热力学和动力学数据库，揭示器件解构和元素分离过程中的污染物组成和迁移规律，发展新能源固废的智能监测、绿色回收、污染控制新方法，为新能源固废工程化应用提供科学与技术支撑，完善资源可循、污染可控的产业链条。

Resource recycling and intelligent monitoring of renewable energy wastes

To mitigate the challenges of the low-utilization rate of critical resources and heavy pollution of end-of-life (EoL) renewable energy devices, we focus on intelligent monitoring, resource recycling, and pollution control of EoL Li-ion batteries, lead-acid batteries, solar panels, wind turbines, functional alloys, etc. The research includes intelligent recognition, remote monitoring (e.g., remote sensing, image recognition, spectral monitoring) and green recycling of retired renewable energy resources. In doing so, we aim to achieve the typical spectral signature and complex elemental occurrence states and structural features of these resources, establish a database about thermodynamic and kinetic behaviors, and reveal the structural dissociation, element beneficiation and separation as well as the pollutant compositions and their migration behaviors in various natural systems. Then we want to develop new technologies encompassing intelligent monitoring, green recycling and pollutant control, offering fundamental and technical support to sustain the practical recycling of EoL renewable energy wastes and establish a sustainable and green supply chain.

资源循环方向的代表论文 (representative articles):

1. Gao SB, Chen X, Qu JK, Guo YY, Shi H, Pang FZ, Guo L, Qu X, Wang DH* & Yin HY*, Recycling of Silicon Solar Panels through a Salt-Etching Approach, Nature Sustainability, 2024, 7(7), 920–930.

2. Qiu BL, Liu MJ, Qu X, Zhou FY, Xie HW, Wang DH, Lee L Y S* & Yin HY*, Waste Plastics Upcycled for High-Efficiency H₂O₂ Production and Lithium Recovery via Ni-Co/Carbon Nanotubes Composites, Nature Communications, 2024, 15(1), 6473.

3. Liu, MJ.; Yang, TC.; Pan, Z.; Lee, J.; An, L.; Qiu, B.; Yin, HY; Yang, C.-M.*; Lee, L. Y. S*. Bridging Li-Ion Batteries and Fuel Cells: From Cathode Leaching Residue to an Atomic-Scale Catalytic System. ACS Energy Letters 2023, 1652-1661.

4. Qiu BL, Liu MJ, Qu X, Zhang BL, Xie HW, Wang DH, Lee L Y S & Yin HY*, Recycling Spent Lithium-Ion Batteries Using Waste Benzene-Containing Plastics: Synergetic Thermal Reduction and Benzene Decomposition, Environmental Science & Technology, 2023, 57(19), 7599–7611.

5. Zhao JJ, Zhou FY, Wang HY, Qu X, Wang DF, Cai YQ, Zheng ZY, Wang DH & Yin HY*, Coupling Electrochemical Leaching with Solvent Extraction for Recycling Spent Lithium-Ion Batteries, Environmental Science & Technology, 2024, 58(38), 16803-16814.

6. Zhou FY, Wang HY, Wang SY, Zhao JJ, Qu X, Wang DF, Cai YQ, Zheng ZY, Wang DH & Yin HY*, Balancing the Components of Biomass and the Reactivity of Pyrolysis Gas: Biomass-Assisted Recycling of Spent LiCoO₂ Batteries, Environmental Science & Technology, 2024, 58(4), 2102–2111.

7. Ma Q, Zhao ZQ, Zhao Y, Xie HW, Xing PF, Wang DH, Yin HY*, A self-driven alloying/dealloying approach to nanostructuring micro-silicon for high-performance lithium-ion battery anodes, Energy Storage Materials, 2021, 34, 768-777.

8. Zhang BL, Qu X, Qu JK, Chen X, Xie HW, Xing PF, Wang DH, Yin HY*, A paired electrolysis approach for recycling spent lithium iron phosphate batteries in an undivided molten salt cell, Green Chemistry, 2020, 22(24), 8633-8641.

9. Qu X, Xie HW, Chen X, Tang YQ, Zhang BL, Xing PF, Yin HY*, Recovery of LiCoO₂ from spent lithium-ion batteries through a low-temperature ammonium chloride roasting approach: thermodynamics and reaction mechanisms, ACS Sustainable Chemistry & Engineering, 2020, 8(16), 6524-6532.

10. Chen X, Zhang BL, Qu X, Zhou FY, Qiu BL, Xie HW, Wang DH, Yin HY*, Recovery of degraded LiCoO₂ through a CO₂-assisted low-temperature thermal reduction approach, Chemical Engineering Journal, 2023, 472, 144749.

二、 能源金属绿色提取与污染控制

针对传统方法提取能源金属过程中污染大和能耗高的问题，开展能源金属（Li、Na、Mg、Co、Pb、Zn、Sb、Re、Ti等）绿色提取理论和方法的研究，研究能源金属在典型矿物和废物（废合金、废盐、废水）中的赋存状态和理化性能，获得能源金属在不同体系中化学键转化的热力学和动力学数据，揭示提取和分离过程中的污染物组成和演变规律，发展利用电子替代传统化学试剂进行元素提取和分离的电解新方法，为能源金属的绿色提取提供新路径。

Green extraction of energy metals and pollution control

To solve the heavy pollution and high energy consumption of conventional methods for energy metal extraction, we focus on fundamental research and novel methods for the extraction of energy metals such as Li, Na, Mg, Co, Pb, Zn, Sb, Re, and Ti. The research mainly studies the elemental occurrence states and physicochemical properties of metal elements in typical minerals and waste (e.g., alloys, salts, wastewater, etc.), and thermodynamic and kinetic behaviors of the chemical-bond transition of these metals in different systems. Then, we aim to reveal the pollutant compositions and their evolution behaviors, thereby developing new electrochemical extraction and separation methods to use electrons as a clean reagent to replace traditional chemicals that have a high environmental footprint. Our goal is to pave a clean way for the extraction of energy metal with less or no secondary waste.

金属提取与污染控制方向的代表论文(representative articles)：

1. Qu JK, Chen X, Xie HW, Gao SB, Wang DH & Yin HY*, Anode Electrolysis of Sulfides, PNAS, 2022, 119(31),1-7.

2. Yin, HY; Chung, B.; Sadoway, D. R.* Electrolysis of a molten semiconductor. Nature Communications 2016, 7 (1), 12584.

3. Liu W, Wang XT, Wang F, Du KF, Zhang ZF, Guo YZ, Yin HY* & Wang DH*, A Durable and pH-Universal Self-Standing MoC–Mo₂C Heterojunction Electrode for Efficient Hydrogen Evolution Reaction, Nature Communications, 2021, 12(1), 6776.

4. Guo L, Yin HY*, Li WM, Wang SY, Du KF, Shi H, Wang X, Wang DH, Liquid-metal-electrode-assisted electrolysis for the production of sodium and magnesium, Journal of Magnesium and Alloys, 2025, 13(4), 1579-1591.

5. Guo L, Gao S, Hu Z, Wu Y, Pang F, Yin HY* & Wang DH, An electrolysis–displacement–distillation approach for the production of Li, Mg, Ca, Sr, and Ba metals, Green Chemistry, 2024, 26(5), 2763-2772.

6. Zhao HJ, Zhao ZQ, Qu JK, ChenX, Zhou FY, Xie HW, Wang DH, Yin HY*, A combined oxidation and salt-thermal approach to converting copper scraps to copper oxides as energy storage materials, Journal of Cleaner Production, 2021, 320, 128870.

7. Qu JK, Xie HW, Song QS, Ning ZQ, Zhao HJ, Yin HY*, Electrochemical desulfurization of solid copper sulfides in strongly alkaline solutions, Electrochemistry Communications, 2018, 92, 14-18.

8. Zhao ZQ, Cai MY, Zhao HJ, Ma Q, Li XY, Xie HW, Xing PF, Zhuang YX, Yin HY*, Metallothermic Reduction of Silica–Carbon Composites: Revealing the Relationship Between Silicon-Based Products and the Reactivity of Reductants, Metallurgical and Materials Transactions B, 2022, 53(4), 2753-2762.

9. Ma X, Xie HW, Qu JK, Song QS, Ning ZQ, Zhao HJ, Yin HY*, An electro-assisted powder metallurgical route for the preparation of porous Ti and NiTi in molten CaCl₂, Metallurgical and Materials Transactions B, 2019, 50(2), 940-949.

10. Wu YX, Cai MY, Wang HY, Hu ZJ, Pang FZ, Chen X, Zhao MY, Wang BB, Zhang X, Liu XW, Wang DH, Yin HY*, An Electrochemical Approach to Prepare Liquid Sodium-Lead Alloy using a Molten NaCl-Na₂CO₃ Electrolyte, Metallurgical and Materials Transactions B, 2025, 56，4010–4024.

三、电化学技术-人工智能-可持续发展

面向低碳、新能源、人工智能和生态文明建设协同发展的迫切需求，以新能源驱动的工业电气化是实现“双碳战略”目标和可持续发展的有效手段。在此背景下，亟需发展新型电化学技术驱动金属冶炼、二氧化碳捕集与转化、电解储能、电化学合成化学品等新技术，利用人工智能、机器学习、全生命周期评价等手段构建大数据模型并对工艺进行预测，获得电解技术全生命周期的碳排放、能量核算、环境效应数据，指导并优化电化学工艺设计，为企业和政府政策制定提供支撑。

Green extraction of energy metals and pollution control

We are living in an era with an urgent need to achieve a low-carbon, intelligent, renewable energy-driven, and ecologically benign society. In this context, the electrification of industry driven by renewable energy is an effective way to meet the double-carbon goals and sustainable development. We focus on developing novel electrolyzers applied in metal extraction, CO₂ capture and conversion, electrolysis for energy storage, electrochemical synthesis, etc. By adopting artificial intelligence, machine learning and life-cycle assessment (LCA) methods, we aim to build a big-data based model to predict the outputs of our technologies. Therefore, we will achieve the data of carbon emissions, energy flows and environmental effects, guiding the optimization of electrochemical technologies and offering advice for entrepreneurs and government officials who make policies.

电化学技术-人工智能-可持续发展方向的代表论文(representative articles)：

1. Yin HY, Chung B, Chen F, Ouchi T, Zhao J, Tanaka N & Sadoway D. R.*, Faradaically selective membrane for liquid metal displacement batteries, Nature Energy, 2018, 3(2), 127-131.

2. Cai MY, Wang SY, Wang HY, Zhou FY, Tang MY, Zhang XD, Qu X, Wang DF, Wang DH, Yin HY*, A Low-Carbon Space-Isolated Zinc Hydrolysis for Harvesting Hydrogen and Salts from Seawater and Wastewater, Angewandte Chemie International Edition, 2025: e12441.

3. Cai MY, Shi H, Zhang Y, Qu JK, Wang HY, Guo YY, Du KF, Li W, Deng BW, Wang DH, Yin HY*, Rechargeable Zn-H₂O Hydrolysis Battery for Hydrogen Storage and Production, Angewandte Chemie International Edition, 2024, 163(26), e202404025.

4. Yin HY, Mao XH, Tang DY, Xiao W, Xing LR, Zhu H, Wang DH & Sadoway D. R.*, Capture and electrochemical conversion of CO₂ to value-added carbon and oxygen by molten salt electrolysis, Energy & Environmental Science, 2013, 6(5), 1538-1545.

5. Zhou FY, Wang HY, Wang SY, Zhao JJ, Qu X, Wang DF, Cai YQ, Zheng ZY, Wang DH & Yin HY*, Balancing the components of biomass and the reactivity of pyrolysis gas: biomass-assisted recycling of spent LiCoO₂ batteries, Environmental Science & Technology, 2024, 58(4), 2102-2111.

6. Cai MY, Wang HY, Shi H, Zhou FY, Zhang XD, Tang MY, Wang DH, Yin HY*, Coupling CO₂ reduction and energy storage by electrolytic zinc, Energy Storage Materials, 2025, 77, 104165.

7. Cai MY, Zhao ZQ, Qu X, Qu JK, Hu ZJ, Shi H, Gao SB, Wang DH, Yin HY*, Refreshing the liquid-gas reaction interface to provoke the zincothermic reduction of SiCl₄ to prepare lithium-storage nano silicon, Energy Storage Materials, 2023, 57, 568-576.

8. Du P, Liu DX, Chen X, Xie HW, Qu X, Wang DH & Yin HY*, Research progress towards the corrosion and protection of electrodes in energy-storage batteries, Energy Storage Materials, 2023, 57, 371-399.

9. Wang SY, Zhao LK, Ye H, Shi Z, Zhang HK, Zhou FY, Xu SM, Xing L, Wang DH* & Yin HY*, Green surfactants powering sustainable batteries: industrial-scale life cycle assessment of Tween and Span surfactants for battery systems, Green Chemistry, 2026, 28(1), 581-593.

10. Wang SY, Zhou FY, Zhao JJ, Wang HY, Cai MY, Wang HC, Wang X, Wang DH* & Yin HY*, Mitigating overestimation in lithium-ion battery recycling LCA: The critical role of ex-post data and operational parameters, Chemical Engineering Journal, 2025, 166261.

学生获奖情况：

国家奖学金: 赵海佳、马强、陈翔、屈佳康、赵晶晶(2)、唐义奇(2)、曲鑫（2）、王丹凤、王洪亚、蔡牧涯、户佐竣、周风银、张超凡

专项奖学金：张贝蕾（优秀博士生科研创新奖）、陈翔（优秀博士生科研创新奖、烟台国冶冶金设备奖学金）、王洪亚（华友钴业奖学金）、蔡牧涯（中天钢铁奖学金、中表镀奖学金）、邱保龙（湘钢奖学金、国家公派留学基金委奖学金）

老王论坛 学术创新奖学金: 赵晶晶、曲鑫、蔡牧涯、周风银

博士青托工程：邱保龙、蔡牧涯、周风银

竞赛获奖：第十九届“挑战杯”全国大学生课外学术科技作品竞赛“揭榜挂帅”专项赛国家一等奖、第三届中国研究生“双碳”创新与创意大赛国家一等奖、第三届全国大学生冶金科技竞赛国家二等奖

近五年来学生就业去向：东北大学、郑州大学、河南师范大学等高校，陕西选调生、比亚迪、宁德时代、宁德新能源、中广核、中核等单位。

近五年来学生升学情况：卡内基梅隆大学，香港理工大学、上海交通大学、老王论坛 、湖南大学等

教学 （Teaching）：

本科生课程 (Undergraduate student courses)：

新生研讨课 (Seminar for freshmen of the department of environmental science and engineering)

绿色低碳技术 (green and low-carbon technologies)

物理性污染 (Physical Pollution)

环境科学与工程导论 (Introduction of environmental science and engineering)

研究生课程 (Graduate student courses)：

环境功能材料（Environmental and functional materials）