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中国科学技术大学博士生导师教师师资介绍简介-明军

本站小编 Free考研考试/2021-04-21

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明军
单位:长春应用化学研究所
地址:吉林省长春市人民大街5625号中科院长春应化所西门
邮编:130022
电话:86-
个人主页: https://orcid.org/0000-0001-9561-5718
实验室介绍:


个人简历 Personal resume


明军,中国科学院长春应用化学研究所研究员。2012年获得中国科学院长春应用化学研究所博士学位,2012-2017年分别在韩国汉阳大学Yang-Kook Sun、日本东京大学Atsuo Yamada、沙特阿卜杜拉国王科技大学Lain-Jong Li、Husam N. Alshareef等世界知名课题组开展博士后研究工作。2017年12月入职中国科学院长春应用化学研究所。研究课题主要包括金属(离子)(锂、钠、钾)电池材料及电解液关键问题及技术等。研究内容立足于基础,以解决企业界在电池材料制备、电解液配方以及电池设计等方面的难题为目标,服务于电池产品的实际应用。提出Li+溶剂化结构对电极稳定性的重要影响,重新认识电解液添加剂作用,以及预测电极稳定性的界面模型。近5年已发表与金属(离子)电池研究相关学术论文100余篇,其中,第一作者及通讯作者论文60余篇,H-index 32。申请美国发明专利4项,中国发明专利1项。国内外指导硕博士20余名。2017-2019年主持研究所、国重室、国防军工及企业科研项目5项。与美国、德国、瑞士、韩国、日本、沙特、意大利等国家的电池知名课题组建有良好的合作关系。


研究方向 Research direction


1、电解液理论及配方设计
2、电极材料及界面分析
3、电池设计及失效分析



招生信息 Enrollment information


欢迎有化学化工物理等专业背景的考生报考,尤其对能源领域(锂/钠/钾离子电池)感兴趣的同学。


论文专著 The monograph


1)Electrolyte-Mediated Stabilization of High Capacity Micro-Sized Antimony Anodes for Potassium-Ion Batteries - Advanced Materials - 2021 - **
2)Unraveling New Role of Ethylene Carbonate Solvation Shell in Rechargeable Metal Ion Batteries - ACS Energy Letters - 2020 - 6, 69-78
3)Model-based Design of Stable Electrolytes for Potassium Ion Batteries - ACS Energy Letters - 2020 - 5, 3124-3131
4)Model-based Design of Graphite Compatible Electrolytes in Potassium Ion Batteries - ACS Energy Letters - 2020 - 5, 2651-2661
5)Additives Engineered Nonflammable Electrolyte for Safer Potassium Ion Battery - Advanced Functional Materials - 2020 - 30, **
6)Unraveling Metal Oxide Role in Exfoliating Graphite: New Strategy to Construct High‐Performance Graphene‐Modified SiOx ‐Based Anode for Lithium‐Ion Batteries - Advanced Functional Materials - 2020 - 30, **
7)Engineering Sodium-Ion Solvation Structure to Stabilize Sodium Anodes: Universal Strategy for Fast-Charging and Safer Sodium-Ion Batteries - Nano Letters - 2020 - 20, 3247-3254
8)An Empirical Model for the Design of Batteries with High Energy Density - ACS Energy Letters - 2020 - 5, 807-816
9)Electrolyte Engineering Enables High Stability and Capacity Alloying Anodes for Sodium and Potassium Ion Batteries - ACS Energy Letters - 2020 - 5, 766-776
10)Understanding Ostwald Ripening and Surface Charging Effects in Solvothermally‐Prepared Metal Oxide–Carbon Anodes for High Performance Rechargeable Batteries - Advanced Energy Materials - 2019 - 9, **
11)Molecular-Scale Interfacial Model for Predicting Electrode Performance in Rechargeable Batteries - ACS Energy Letters - 2019 - 4, 1584-1593
12)New Insight on the Role of Electrolyte Additives in Rechargeable Lithium Ion Batteries - ACS Energy Letters - 2019 - 4, 2613-2622
13)New Organic Complex for Lithium Layered Oxide Modification: Ultrathin Coating, High-Voltage, and Safety Performances - ACS Energy Letters - 2019 - 4, 656-665
14)An Exploration of New Energy Storage System: High Energy Density, High Safety, and Fast Charging Lithium Ion Battery - Advanced Functional Materials - 2018 - 29, **
15)Recognizing the mechanism of sulfurized polyacrylonitrile cathode materials for Li–S batteries and beyond in Al–S batteries - ACS Energy Letters - 2018 - 3, 2899-2907
16)Phase inversion strategy to flexible freestanding electrode: critical coupling of binders and electrolytes for high performance Li–S battery - Advanced Functional Materials - 2018 - 28, **
17)New insights on graphite anode stability in rechargeable batteries: Li ion coordination structures prevail over solid electrolyte interphases - ACS Energy Letters - 2018 - 3, 335–340
18)Metal-Organic Framework-Based Separators for Enhancing Li-S Battery Stability: Mechanism of Mitigating Polysulfide Diffusion - ACS Energy Letters - 2017 - 2, 2362-2367
19)Multilayer Approach for Advanced Hybrid Lithium Battery - ACS Nano - 2016 - 10, 6037-6044
20)Redox Species-Based Electrolytes for Advanced Rechargeable Lithium Ion Batteries - ACS Energy Letters - 2016 - 1, 529-534



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