自2019年開始,為使本科生仍能體驗(yàn)海外全英文課程,開拓國際學(xué)術(shù)視野,材料學(xué)院與南洋理工大學(xué)(NTU)合作開展暑期線上課程項(xiàng)目。基于前期良好的反饋效果,今年計(jì)劃繼續(xù)實(shí)施。現(xiàn)通知如下:
南洋理工大學(xué)(Nanyang Technological University,NTU),是新加坡的一所世界著名研究型大學(xué),其在納米材料、生物材料、功能性陶瓷和高分子材料等許多領(lǐng)域的研究享有世界盛名。2022年綜合QS排名世界第19位,材料學(xué)科QS排名第3位。
一、申請對象
全體本科生
二、項(xiàng)目時(shí)間
初定7月中下旬,8次課
三、項(xiàng)目費(fèi)用
參照相關(guān)規(guī)定,順利完成項(xiàng)目經(jīng)認(rèn)定后可獲得第四課堂學(xué)分,并按照學(xué)校和學(xué)院政策對本項(xiàng)目全額資助。但無故屢次缺勤或態(tài)度不認(rèn)真的學(xué)生將不予資助。
四、學(xué)分認(rèn)定
根據(jù)本科生院規(guī)定,所有本科生均要取得第四課堂學(xué)分,才準(zhǔn)予畢業(yè)。第四課堂學(xué)分認(rèn)定需在校期間有至少一次出國(境)經(jīng)歷,今年參加本次線上課程亦可繼續(xù)認(rèn)定第四課堂學(xué)分,且不影響今后出國(境)的機(jī)會和資助名額。表現(xiàn)優(yōu)異者,可優(yōu)先推薦參加今后院級出國(境)交流項(xiàng)目。
五、報(bào)名方式
點(diǎn)擊鏈接,填寫擬報(bào)名申請表:https://www.wjx.cn/vm/O35Nihs.aspx#
報(bào)名截止時(shí)間為6月10日
六、咨詢方式
項(xiàng)老師 xiangtt@zju.edu.cn 電話:87953141
七、項(xiàng)目信息
Introduction to Energy Storage (NTU)
《能源存儲導(dǎo)論》
Duration:
16 lecture hours ( 1 lecture hour= 45 minutes)
Learning objective:
The course aims to introduce the concept of energy storage technology through batteries. It would teach students the basic concepts of batteries and challenges in battery development. The course includes supercapacitor and batteries concepts, lithium ion battery technology, essential techniques and technology of batteries/supercapacitors through understanding the underlying kinetics and thermodynamics of electrode processes occurring in various batteries.
Course outline:
Topic | Lecture hours |
1. INTRODUCTION TO ENERGY STORAGE TECHNOLOGIES Basics of energy storage, Types of energy storage, Capacitors vs Ultra capacitors/ supercapactiors, Rechargeable and non-rechargeable batteries, Similarities and differences between supercapacitors and batteries for energy storage, prospects and challenges in energy storage. | 2 |
2. SUPERCAPACITORS AND BATTERIES FOR ENERGY STORAGE Design of supercapacitors, Symmetric/Asymmetric supercapacitors, Charge storage mechanisms, Pseudocapacitance effects, Energetics and kinetics of electrode processes, Ragone plot, Nanomaterials for energy storage, Design and standardization, Selection and applications, Hybrid electrochemical capacitors, Prospects and challenges. | 4 |
3. LITHIUM ION BATTERIES Lithium primary batteries, Rocking chair concept, Intercalation compounds, Role of electrolytes in lithium ion batteries, Transition metal oxides, Advantages/disadvantages of Li-ion batteries over other energy storage technologies, ‘C’ rate, Safety issue in lithium ion cells, Thin film and Polymer batteries, Advances and future of LiON battery technology in mobile applications and Hybrid Electric vehicles (HEV). | 4 |
4. PERFORMANCE METRICS FOR EVALUATING ELECTROCHEMICAL ENERGY STORAGE DEVICES Charge-Discharge characteristics, Self- discharge, Cycling efficiency, Rate capability, Power/energy density, Specific capacity, Factors affecting supercapacitor/ battery performance, Study of electrode/electrolyte interface, Galvanostatic/Potentiostatic studies, Impedance measurements, Voltammetric techniques. | 4 |
5. Case studies, tutorials and exam | 2 |
Professor’s profile:
Qingyu Yan is currently a professor in School of Materials Science and Engineering in Nanyang Technology University. He obtained his BS in Materials Science and Engineering, Nanjing University. He finished his PhD from Materials Science and Engineering Department of State University of New York at Stony Brook. After that, He joined the Materials Science and Engineering Department of Rensselaer Polytechnic Institute as a postdoctoral research associate. He joined School of Materials Science and Engineering of Nanyang Technological University as an assistant professor in early 2008 and became a Professor in 2018.
He is currently the Chair of the Electrochemical Society, Singapore Section. He is a fellow of Royal Society of Chemistry Since 2018. He is a highly cited researcher in Materials Science for 2018 indicated by Thomson Reuters. Yan has published more than 280 papers (with total citation of >19000 and h index of 73) on two research area: (1) thermoelectric materials; (2) electrochemical properties of materials for energy storage or conversion.
