电子邮件: suoliumin@iphy.ac.cn
通信地址: 北京市海淀区中关村南三街8号
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个人简介
2013年于中国科学院物理研究所获理学博士学位, 曾先后在在美国马里兰大学 (2013-2016), 美国麻省理工学院 (MIT)(2016~2017)从事博士后研究工作。2017年10月加入中国科学院物理研究所,在清洁能源实验室纳米离子学与能源材料E01组工作, 任特聘研究员, 博士生导师。近年来发表SCI论文共计60篇 (IF >10, 38 篇), 引用次数:> 1000次(2 篇)、> 100次(20 篇)。第一作者/通讯作者身份发表文章31 篇,包括Science、Nature Energy, Nature Communications、PNAS、Adv. Mater (4), Angew. (3)、JACS、Matter、Adv. Energy Mater. (3)、ACS Nano/Nano Letter (3) 等。文章发表以来 SCI 引用次数大于7700次,其中60%以上源于第一作者/通讯作者论文贡献,H因子 37。
主要研究方向
新型二次电池体系的基础研究与开发,具体涵盖如下:
(1)新型电解液体系探索开发及相关基础科学问题研究
(2)安全、绿色、低成本水系碱金属二次电池研究(锂/钠离子电池)
(3)高能量密度金属锂基电池 (锂硫电池/金属锂电池)
(4)高能量密度多价转移二次电池体系(铝电池/镁电池)
招生专业
招生方向
研究成果
1 高盐浓度电解液基础研究及在新电池体系中的应用
(1)提出新型宽电位窗口高盐浓度Water-in-Salt水系电解质及其在水系二次电池中应用
将水系电解液电化学窗口由低于2.0V提高至3.0V, 为实现长寿命高压水系锂/钠离子电池提供了必要前提。 在水 系电解液中实现SEI膜, 推翻前人对水系锂电池无法形成SEI膜的认识,从根本上解决了水系二次电池“析氢问题”而导致循环寿命低的关键技术难题。将水系全电池输出电压由 < 1.5 V提高至 > 2 V 。
a. 锂基Water-in-Salt电解液 (Science, 2015 [引用 > 1200])
b. 锂基Water-in-Bisalt电解液 (Angew. Chem. Int. Edit. , 2016 [引用 > 300])
c. 提出水系SEI膜形成机制 (JACS, 2017 [引用 > 100])
d. 钠基Water-in-salt电解质 (Adv. Energ. Mater. 2017 [引用 > 100])
e. 钠基IC-Water-in-salt电解液 (Adv. Mater. 2020)
f. Water-in-salt 离子输运机制研究 (ACS Nano, 2017 [引用 > 100])
g. Water-in-salt 抑制电极溶解机制研究 (Adv.Energ. Mater. 2020)
h. 铝基Water-in-salt电解液 (ACS Applied Materials Interface. 2019)
(2)开拓了有机体系高盐浓度电解液及其在金属锂电池中应用
提出高盐浓度电解质稳定金属锂负极想法,为提高金属锂循环稳定性和抑制锂枝晶提供了一种全新解决思路。将高盐浓度电解液用于锂硫电池同时解决了多硫离子溶解和稳定金属锂负极两项关键技术难题。
a. 金属锂基用Solvent-in-Salt新型双功能电解质 (Nat. Commun., 2013,[引用:> 1500] )
b. 提出高能量密度金属锂电池用5V全氟电解液体系 (PNAS, 2018. [引用: > 200] )
2. 高能量密度金属锂基电池
(1)高能量密度锂-硫电池
a. 将锂硫电池用高盐浓度Solvent-in-Salt双功能电解质 (Nat. Commun., 2013,[引用:> 1500] )
b. 提出嵌入-转化混合硫正极实现高体积和能量密度锂硫电池 (Nature Energy, 2019, [引用: > 100]
c. 开发了一种高电子-离子电导电化学活性多功能隔膜涂层用于锂硫电池 (Matter, 2019)
d. 提出超轻电解液提高锂硫电池全电池能量密度> 20 % (Agew, 2021)
(2)无负极金属锂二次电池
a. 开发富锂层状三元正极材料提升高能量密度无负极金属锂电池循环寿命 (Agew, 2021)
b. 提出液态金属涂层集流体诱导外延锂沉积实现无负极锂金属电池长寿命 (AEM, 2021)
3. 高离子/电子导电电极材料提升电池能量密度
(1)提出全活性物质全固态金属锂电池 (Adv. Mater. 2021)
(2) 高电子导电无机-有机复合正极材料提升有机全电池能量密度 (Adv. Mater. 2021)
(3) 嵌入-转化混合型富硫正极实现高体积和能量密度锂硫电池 (Nature Energy, 2019, [引用: > 100])
(4)锂硫电池用高电子-离子电导电化学活性多功能涂层隔膜 (Matter, 2019)
4. 多价转移铝/镁电池
(1) 镁离子电池
a. 碘蒸气辅助合成纳米片状硫化钼镁离子正极(ACS Nano, 2020)
b. 阳离子-阴离子共还原高容量黄铁矿型镁离子正极 (Nano Letter 2020)
(2)铝离子电池
a. bipolar 双极柔性铝离子电池(ACS Materials Letter, 2020)
b. 铝离子有机正极 (JMCA, 2020)
代表性论文及专利:
2017年10 月 加入物理所后
一. 发表研究论文:第一作者/通讯作者文章:22 篇 (* 通信作者:20 篇,一作:2 篇)
- Nature Energy (1)
- PNAS (1)
- Adv. Mater. (4) / Agew (2) / JACS (1) / JACS Au (1) /Matter (1)
- Adv. Energ. Mater. (2) / ACS Energy Letter (1)
- Nano Letter(1) / ACS Nano (1)
- Energy Storage Material (1)
- ACS Materials Letter (1) / ACS Applied Materials Interface (1)
- JMCA (1) /ACS Applied Energy Materials (1) / JPCC(1)
--------------------------------------------2021 年 -------------------------------------------
26. Tao Liu, Liumin Suo*, et.al. Low-Density Fluorinated Solane Solvent Lasting Deep Cycle Lithium-Sulfur Batteries Life Advanced Materials, (2021)
25. Tao Liu, Liumin Suo*, et.al. Ultralight Electrolyte for High-Energy Lithium-Sulfur Pouch Cells. Angew. Chem. Int. Edit, (2021)
25. Minglei Mao, Liumin Suo*, et.al. Amorphous Redox-Rich Polysulfides for Mg Cathode. JACS Au, (2021)
24. Meiying Li, Ju Li*, Liumin Suo*, et.al. Dense all-electrochem-active electrodes for all-solid-state lithium batteries. Advanced Materials, (2021)
23. Liangdong Lin, Liumin Suo*, et.al., Li-Rich Li2[Ni0.8Co0.1Mn0.1]O2 for Anode-Free Lithium Metal Batteries. Angew. Chem. Int. Edit, (2021)
22. Minglei Mao#, Shu Wang#, Liumin Suo*, et.al., Electronic Conductive Inorganic Cathodes Promising High-Energy Organic Batteries. Advanced Materials, (2021)
21. Liangdong Lin, Liumin Suo*, et.al., Epitaxial Induced Plating Current-Collector Lasting Lifespan of Anode-Free Lithium Metal Battery. Advanced Energy Materials, (2021)
20. Pan Tan#, Jinming Yue, Liumin Suo*, Liang Hong* et.al., Solid-like Nano-Anion-Cluster Constructs Free Lithium-ion Conducting Super-Fluid Framework in Water-in-salt Electrolyte. The Journal of Physical Chemistry, (2021)
19. Binghang Liu, Liumin Suo*, et.al., Sandwich Structure Corrosion-Resistant Current Collector for Aqueous Batteries. ACS Applied Energy Materials (2021)
18. Yuxin Tong, Ang Gao, Qinghua Zhang*, Liumin Suo*, Lin Gu* et.al., Cation-synergy stabilizing anion redox of Chevrel phase Mo6S8 in aluminum ion battery. Energy Storage Material. (2021)
17. Binghang Liu, Liumin Suo*, et.al., Sandwich-structure Corrosion-resistant Current Collector for Aqueous Batteries. ACS Applied Energy Materials. (2021)
--------------------------------------------2020 年 -----------------------------------------------------
16. Liwei Jiang, Oleg Borodin*, Liumin Suo*, Yong-Sheng Hu* et.al., High-Voltage Aqueous Na-Ion Battery Enabled by Inert-Cation-Assisted Water-in-Salt Electrolyte. Advanced Materials, 32, (2020)
15. Minglei Mao, Yuxin Tong# Lin Gu*, Liumin Suo*, et.al., Joint Cationic and Anionic Redox Chemistry for Advanced Mg Batteries. Nano Letters, 20, 6852, (2020)
14. Jinming Yue, Liumin Suo*, et.al., Interface Concentrated-Confinement Suppressing Cathode Dissolution in Water-in-Salt Electrolyte. Advanced Energy Materials, 10, (2020)
13. Minglei Mao, Liumin Suo*, et.al., Iodine Vapor Transport-Triggered Preferential Growth of Chevrel Mo6S8 Nanosheets for Advanced Multivalent Batteries. ACS Nano, 14, 1102, (2020)
12. Zejing Lin, Liumin Suo*, et.al., Wearable Bipolar Rechargeable Aluminum Battery. ACS Materials Letter, 2, 808, (2020)
11. Minglei Mao, Miao Liu*, Liumin Suo*, et.al., Simplifying and accelerating kinetics enabling fast-charge Al battery. Journal of Materials Chemistry A, 8, 23834, (2020)
--------------------------------------------2019 年 -----------------------------------------------------
10. Weijiang Xue, Liumin Suo*, Ju Li*, et.al., Intercalation-Conversion Hybrid Cathodes Enabling Li-S Full-Cell Architectures with Jointly Superior Gravimetric and Volumetric Energy Densities. Nature Energy, 4, 374, (2019)
9. Anxing Zhou, Liumin Suo*, et.al., “Water-in-Salt” Electrolyte Promotes High-Capacity Fefe(Cn)(6) Cathode for Aqueous Al-Ion Battery. ACS Applied Materials & Interfaces, 11, 41356, (2019)
8. Weijiang Xue, Liumin Suo*, Ju Li*, et.al., Manipulating sulfur mobility enables advanced Li-S batteries. Matter 1 (4), 1047-1060
7. Lilu Liu, Xingguo Qi, Shijun Yin, Qjangqiang Zhang, Xiaozhi Liu, Liumin Suo*, Hong Li, Liquan Chen and Yong-Sheng Hu*, In Situ Formation of a Stable Interface in Solid-State Batteries. ACS Energy Letters, 4, 1650, (2019)
--------------------------------------------2018 年 -----------------------------------------------------
6. Liumin Suo, Ju Li* et.al., Fluorine-Donating Electrolytes Enable Highly Reversible 5-V-Class Li Metal Batteries. Proceedings of the National Academy of Sciences of the United States of America, 115, 1156, (2018)
5. Liumin Suo, Ju Li*, Kang Xu*, Chunsheng Wang* et.al., How Solid-Electrolyte Interphase Forms in Aqueous Electrolytes. Journal of the American Chemical Society, 139, 18670, (2017)
--------------------------------- 2017 年加入物理所前代表作 ------------------------------------------
4. Liumin Suo, Yong-sheng Hu*, Kang Xu*, Chunsheng Wang* et.al., "Water-in-Salt" Electrolyte Makes Aqueous Sodium-Ion Battery Safe, Green, and Long-Lasting. Advanced Energy Materials, 7, (2017)
3. Liumin Suo, et.al., Advanced High-Voltage Aqueous Lithium-Ion Battery Enabled by "Water-in-Bisalt" Electrolyte. Angewandte Chemie-International Edition, 55, 7136, (2016)
2. Liumin Suo, Chunsheng Wang*, Kang Xu* et.al., "Water-in-Salt" Electrolyte Enables High-Voltage Aqueous Lithium-Ion Chemistries. Science, 350, 938, (2015)
1. Liumin Suo, Yong-sheng Hu* et.al., A New Class of Solvent-in-Salt Electrolyte for High-Energy Rechargeable Metallic Lithium Batteries. Nature Communications, 4, (2013)
二. 邀请撰写约稿综述 (通讯作者)
1. Energy & Fuels 专刊 "Recent Advances on Batteries and Energy Storage in China"
中国水系碱金属离子电池研究进展, Progress in rechargeable aqueous alkali-ion batteries in China(Energy & Fuels, 2021)
指导学生
现指导学生
林泽京 博士研究生 080501-材料物理与化学
岳金明 博士研究生 070205-凝聚态物理
刘秉航 博士研究生 070205-凝聚态物理
秦坤 硕士研究生 080501-材料物理与化学
周安行 博士研究生 080501-材料物理与化学
李华君 硕士研究生 070205-凝聚态物理
吕天莳 博士研究生 070205-凝聚态物理