刘永锋

summary
刘永锋，1977年10月生。浙江大学教授，博士生导师。国家基金委优秀青年基金获得者，国家“****”青年拔尖人才，教育部****奖励计划青年项目，浙江省****基金获得者。
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\r1995-1999 浙江大学 本科
\r2000-2005 浙江大学 博士(硕博连读，2009年获全国优秀博士学位论文提名)
\r2005-2007 National University of Singapore (新加坡国立大学) Research Fellow (博士后研究员)
\r2007-2012 浙江大学 副教授 (2011年入选浙江省钱江人才计划，浙江省151人才工程)
\r2011-2014 浙江大学 求是青年**** (2012年获国家优秀青年基金)
\r2011-至今 浙江大学 博士生导师
\r2012-至今 浙江大学 教授 (2015年入选国家“****”青年拔尖人才，教育部青年****，浙江省****基金)
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\r主要从事储氢材料和锂离子电池电极材料的设计、合成及其性能调控的基础理论和应用研究，在金属配位氢化物储氢材料的纳米化和性能调控、储氢电极合金新体系创制和高容量储锂材料可控制备等方面取得了一系列创新性成果。先后承担\/完成了来自于国家基金委、科技部、教育部、浙江省科技厅等科研项目15 项，申请发明专利53项，授权发明专利37项，包括国际PCT专利1项(日本)。在Nature Communications, Advanced Functional Materials, Journal of American Chemical Society, Energy & Environmental Science, Chemistry of Materials, Journal of Materials Chemistry等知名学术期刊上发表论文190余篇，其中170余篇被SCI 收录(第一\/通讯作者110余篇)，5篇论文被邀封面或封底展示；所发表论文被Web of Science收录的230种期刊的800位作者引用总计4000余次，其中他引3500余次。H 因子为35。应邀撰写综述论文3 篇，编译中文专著1本(储氢材料：储存性能表征，机械工业出版社，2013.10)，撰写英文专著Catalytic Batteries, Hydrogen Storage Materials, and Fuel Cells 中的一章(Chapter 13, Hydrogen Storage Materials, Elsvier出版社，2013.7)。
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\r2009 年获全国优秀博士论文提名奖；2010 年获浙江省自然科学学术奖二等奖，杭州市自然科学优秀学术成果二等奖；2011 年入选浙江省151 人才工程和“钱江人才”计划，获浙江省高校优秀科研成果一等奖，杭州市自然科学学术成果一等奖，杭州市青年科技奖；2012 年获国家优秀青年科学基金资助；2014年入选由Elsevier发布的2014年中国高被引****榜单(能源领域)；2015年入选国家****“青年拔尖人才”，教育部青年长江，获浙江省****基金。
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\r近5年代表性论文目录：
\r[1] Yun Cao, Yaxiong Yang, Zhuanghe Ren, Ni Jian, Mingxia Gao, Yongjun Wu, Min Zhu, Feng Pan, Yongfeng Liu,* and Hongge Pan, A New Strategy to Effectively Suppress the Initial Capacity Fading of Iron Oxides by Reacting with LiBH4, Adv. Funct. Mater., 2017, **.
\r[2] Yaxiong Yang, Yongfeng Liu*, Kaichao Pu, Xing Chen, He Tian, Mingxia Gao, Min Zhu, and Hongge Pan, Highly Stable Cycling of Amorphous Li2CO3-coated α-Fe2O3 Nanocrystallines Prepared via a New Mechanochemical Strategy for Li-ion Batteries, Adv. Funct. Mater., 2017,160511.
\r[3] Shiming Zhang, Haitao Gu, Hongge Pan,* Suhui Yang, Wubin Du, Xiang Li, Mingxia Gao, Yongfeng Liu,* Min Zhu, Liuzhang Ouyang, Dechao Jian, and Feng Pan, A Novel Strategy to Suppress Capacity and Voltage Fading of Li- and Mn-Rich Layered Oxide Cathode Material for Lithium-Ion Batteries, Adv. Energy Mater., 2016, **.
\r[4] Xin Zhang, Ruyan Wu, Zeyi Wang, Mingxia Gao, Hongge Pan and Yongfeng Liu*, Preparation and Catalytic Activity of a Novel Nanocrystalline ZrO2@C Composite for Hydrogen Storage in NaAlH4, Chem. Asian J., 2016,11, 3541-3549.
\r[5] Ruyan Wu, Hufei Du, Zeyi Wang, Mingxia Gao, Hongge Pan, Yongfeng Liu*, Remarkably improved hydrogen storage properties of NaAlH4 doped with 2D titanium carbide, J. Power Sources, 2016, 327, 519-525.
\r[6] You Li, Yongfeng Liu,* Xin Zhang, Di Zhou, Yunhao Lu, Mingxia Gao and Hongge Pan, An ultrasound-assisted wet-chemistry approach towards uniform Mg(BH4)2·6NH3 nanoparticles with improved dehydrogenation properties, J. Mater. Chem. A, 2016, 4, 8366–8373.
\r[7] Yongfeng Liu*, Yaxiong Yang, Mingxia Gao and Hongge Pan*, Tailoring Thermodynamics and Kinetics for Hydrogen Storage in Complex Hydrides towards Applications, Chemical Record, 2016, 16, 189-204.
\r[8] Yongfeng Liu, Xin Zhang, Ke Wang, Yaxiong Yang, Mingxia Gao, and Hongge Pan, Achieving Ambient Temperature Hydrogen Storage in Ultrafine Nanocrystalline TiO2@C-doped NaAlH4, J. Mater. Chem. A, 2016, 4, 1087–1095.
\r[9] Yongfeng Liu, Hufei Du, Xin Zhang, Yaxiong Yang, Mingxia Gao, Hongge Pan*, Superior catalytic activity derived from two-dimensional Ti3C2 precursor towards the hydrogen storage reaction of magnesium hydride, Chem. Commun., 2016, 52, 705-708
\r[10]Xin Zhang, Yongfeng Liu*, Ke Wang, You Li, Mingxia Gao, and Hongge Pan, Ultrafine Nanocrystalline CeO2@C-Containing NaAlH4 with Fast Kinetics and Good Reversibility for Hydrogen Storage, ChemSusChem, 2015, 8, 4180-4188.
\r[11]Yi Zhang, Yongfeng Liu*, Xin Zhang, You Li, Mingxia Gao, Hongge Pan, Synthesis of Nanosized Carbon Supported Ni Composite and Its Remarkable Catalysis for Hydrogen Desorption from the LiBH4-2LiNH2 System, J. Phys. Chem. C 2015, 119, 24760−24768.
\r[12]Yuepeng Pang, Yongfeng Liu*, Xin Zhang, Qian Li, Mingxia Gao, Hongge Pan, Composition-dependent reaction pathways and hydrogen storage properties of LiBH4\/Mg(AlH4)2 composites, Chem. Asian J., 2015, 10, 2452-2459.
\r[13]Yongfeng Liu, Yaxiong Yang, Xin Zhang, You Li, Mingxia Gao and Hongge Pan*, Insights into the dehydrogenation reaction process of a K containing Mg(NH2)2‐2LiH system, Dalton Trans., 2015, 44, 18012 –18018.
\r[14]Yi Zhang, Yongfeng Liu,* Xin Zhang, You Li, Mingxia Gao and Hongge Pan, Mechanistic understanding of the CoO-catalyzed hydrogen desorption from a LiBH4·NH3-3LiH system, Dalton Trans., 2015, 44, 14514 – 14522.
\r[15]Ruijun Ma, Yongfeng Liu,*, Yaxiong Yang, Kaichao Pu, Mingxia Gao, Hongge Pan, Li-Si-alloy-assisted improvement in the intrinsic cyclability of Mg2Si as an anode material for Li-ion batteries, Acta Mater., 2015, 98, 128-134
\r[16]Yanjing Yang, Yongfeng Liu*, You Li, Xin Zhang, Mingxia Gao and Hongge Pan*, Towards the endothermic dehydrogenation of nanoconfined magnesium borohydride ammoniate, J. Mater. Chem. A, 2015, 3, 11057-11065.
\r[17]Yongfeng Liu, Ping Yan, Ruijun Ma, Mingxia Gao, Hongge Pan*, Electrochemical properties of the ternary alloy Li5AlSi2 synthesized by reacting LiH, Al and Si as an anodic material for lithium-ion batteries, J. Power Sources, 2015, 283, 54-56.
\r[18]Xin Zhang, Yongfeng Liu*, Ke Wang, Mingxia Gao, and Hongge Pan, Remarkably Improved Hydrogen Storage Properties of Nanocrystalline TiO2-modified NaAlH4 and Evolution of Ti-containing Species during De-\/Hydrogenation, Nano Research, 2015, 8, 533-545.
\r[19]Yanjing Yang, Yongfeng Liu*, You Li, Mingxia Gao and Hongge Pan*, Fluorine-substituted Mg(BH4)2·2NH3 with improved dehydrogenation properties for hydrogen storage, J. Mater. Chem. A, 2015, 3, 570-578.
\r[20]Mingxia Gao, Dingsheng Wang, Xuqing Zhang, Hongge Pan,* Yongfeng Liu, Chu Liang, Congxiao Shang and Zhengxiao Guo, A hybrid Si@FeSiy\/SiOx anode structure for high performance lithium-ion batteries via ammonia-assisted one-pot synthesis, J. Mater. Chem. A, 2015, 3, 10767-10776.
\r[21]Ruijun Ma, Yongfeng Liu*, Yaxiong Yang, Mingxia Gao, Hongge Pan, Mg2Si anode for Li-ion batteries: Linking structural change to fast capacity fading, Appl. Phys. Lett., 2014 105, 213901.
\r[22]Chao Li, Yongfeng Liu*, Ruijun Ma, Xin Zhang, You Li, Mingxia Gao, and Hongge Pan, Superior Dehydrogenation\/Hydrogenation Kinetics and Long-Term Cycling Performance of K and Rb Cocatalyzed Mg(NH2)2 2LiH system, ACS Appl. Mater. Interfaces 2014, 6, 17024−17033.
\r[23]Yu Zhang, Yongfeng Liu*, Yuepeng Pang, Mingxia Gao and Hongge Pan, Role of Co3O4 in improving the hydrogen storage properties of a LiBH4-2LiNH2 composite, J. Mater. Chem. A, 2014, 2, 11155 – 11161.
\r[24]Yongfeng Liu, Ruijun Ma, Yanping He, Mingxia Gao and Hongge Pan*, Synthesis, Structure Transformation and Electrochemical Properties of Li2MgSi as a Novel Anode for Li-ion Batteries, Adv. Funct. Mater., 2014, 24, 3944-3952.
\r[25]Chao Li, Yongfeng Liu,* Yanjing Yang, Mingxia Gao and Hongge Pan*, High-temperature failure behaviour and mechanism of K-based additives in Li-Mg-N-H hydrogen storage systems, J. Mater. Chem. A, 2014, 2, 7345–7353
\r[26]Yuepeng Pang, Yongfeng Liu*, Mingxia Gao, Liuzhang Ouyang, Jiangwen Liu, Hui Wang, Min Zhu, Hongge Pan*, A mechanical-force-driven physical vapour deposition approach to fabricating complex hydride nanostructures, Nature Commun., 2014, 5, 3519.
\r[27]Ruijun Ma, Yongfeng Liu*, Ping Yan, Mingxia Gao, Hongge Pan*, A facile method for determining a suitable voltage window for an amorphous Li12Si7 anode, Electrochim. Acta, 2014, 129, 373-378
\r[28]Bo Li, Yongfeng Liu*, Chao Li, Mingxia Gao, and Hongge Pan, In situ formation of lithium fast-ion conductor and improved hydrogen desorption properties of LiNH2\/MgH2 system with the addition of lithium halides, J. Mater. Chem. A, 2014, 2, 3155-3162.
\r[29]Xin Zhang, Yongfeng Liu*, Yuepeng Pang, Mingxia Gao, and Hongge Pan, Significantly improved kinetics, reversibility and cycling stability for hydrogen storage in NaAlH4 with the Ti-incorporated metal organic framework MIL-125(Ti), J. Mater. Chem. A, 2014, 2, 1847–1854
\r[30]Chao Li, Yongfeng Liu*, Yuepeng Pang, Yingjie Gu, Mingxia Gao and Hongge Pan*, Compositional effects on the hydrogen storage properties of Mg(NH2)2–2LiH–xKH and the activity of KH during dehydrogenation reactions, Dalton Trans., 2014, 43, 2369–2377.
\r[31]Yanjing Yang, Yongfeng Liu*, Hui Wu, Wei Zhou, Mingxia Gao, and Hongge Pan*, An Ammonia-stabilized Mixed-cation Borohydride: Synthesis, Structure and Thermal Decomposition Behavior, Phys. Chem. Chem. Phys., 2014, 16 (1), 135 - 143.
\r[32]Chao Li, Yongfeng Liu*, Yingjie Gu, Mingxia Gao and Hongge Pan, Improved Hydrogen-Storage Thermodynamics and Kinetics for an RbF-Doped Mg(NH2)2–2 LiH System, Chem. Asian J. 2013, 8, 2136 – 2143.
\r[33]Mingxia Gao, Jian Gu, Hongge Pan, Yiliu Wang, Yongfeng Liu, Chu Liang and Zhengxiao Guo, Ca(BH4)2–LiBH4–MgH2: a novel ternary hydrogen storage system with superior long-term cycling performance, J. Mater. Chem. A, 2013, 1, 12285-12292.
\r[34]Yanjing Yang, Yongfeng Liu*, You Li, Mingxia Gao, and Hongge Pan, Heating Rate-Dependent Dehydrogenation in the Thermal Decomposition Process of Mg(BH4)2·6NH3, J. Phys. Chem. C, 2013, 117, 16326–16335.
\r[35]Jian Gu, Mingxia Gao, Hongge Pan, Yongfeng Liu, Bo Li, Yanjing Yang, Chu Liang, Hongliang Fu and Zhengxiao Guo, Improved hydrogen storage performance of Ca(BH4)2: a synergetic effect of porous morphology and in situ formed TiO2, Energy Environ. Sci., 2013, 6, 847–858.
\r[36]Chu Liang, Yongfeng Liu*, Mingxia Gao and Hongge Pan*, Understanding the role of K in the significantly improved hydrogen storage properties of a KOH-doped Li–Mg–N–H system, J. Mater. Chem. A, 2013, 1, 5031–5036.
\r[37]Hongge Pan*, Songbo Shi, Yongfeng Liu*, Bo Li, Yanjing Yang, Mingxia Gao, Improved hydrogen storage kinetics of the Li-Mg-N-H System by Addition of Mg(BH4)2, Dalton Trans., 2013, 42, 3802–3811
\r[38]Yanjing Yang, Yongfeng Liu*, You Li, Mingxia Gao, Hongge Pan, Synthesis and Thermal Decomposition Behaviors of Magnesium Borohydride Ammoniates with Controllable Composition as Hydrogen Storage Materials, Chem. Asian J. 2013, 8, 476 – 481
\r[39]Yongfeng Liu, Chao Li, Bo Li, Mingxia Gao, and Hongge Pan, Metathesis Reaction-Induced Significant Improvement in Hydrogen Storage Properties of the KF-Added Mg(NH2)2−2LiH System, J. Phys. Chem. C 2013, 117, 866−875
\r[40]Bo Li, Yongfeng Liu*, Jian Gu, Mingxia Gao, and Hongge Pan, Synergetic Effects of in Situ Formed CaH2 and LiBH4 on Hydrogen Storage Properties of the Li-Mg-N-H System, Chem. Asian J. 2013, 8, 374 – 384
\r[41]Ruijun Ma, Yongfeng Liu*, Yanping He, Mingxia Gao, and Hongge Pan*, Chemical Preinsertion of Lithium: An Approach to Improve the Intrinsic Capacity Retention of Bulk Si Anodes for Li-ion Batteries, J. Phys. Chem. Lett. 2012, 3, 3555−3558.
\r[42]Yongfeng Liu, Yanping He, Ruijun Ma, Mingxia Gao, Hongge Pan*, Improved lithium storage properties of Mg2Si anode material synthesized by hydrogen-driven chemical reaction, Electroch. Commun. 2012, 25, 15–18
\r[43]Bo Li, Yongfeng Liu*, Yu Zhang, Mingxia Gao, and Hongge Pan, Reaction Pathways for Hydrogen Uptake of the Li−Mg−N-Based Hydrogen Storage System, J. Phys. Chem. C 2012, 116, 13551−13558.
\r[44]YiFan Zhou, Yongfeng Liu*, Yu Zhang, Mingxia Gao, and Hongge Pan, Functions of MgH2 in hydrogen storage reactions of the 6LiBH4–CaH2 reactive hydride composite, Dalton Trans., 2012, 41, 10980-10987.
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\r授权国家发明专利：
\r[1] 刘永锋，杨亚雄，高明霞，潘洪革，一种硅氧碳复合锂离子电池负极材料的制备方法，申请号：4.0，申请日: 2015.01.09，授权日期：2017.5.17
\r[2] 刘永锋，杨亚雄，高明霞，潘洪革，一种多元多相复合锂离子电池负极材料的制备方法，申请号:8.8，申请日:2015.05.19，授权日期：2017.4.19
\r[3] 刘永锋，杨亚雄，高明霞，潘洪革，一种金属氧化物锂离子电池负极材料的制备方法，申请号：ZL8.2，申请日:2015.05.19，授权日期：2017.2.22
\r[4] 刘永锋 庞越鹏 潘洪革 高明霞，METHOD FOR PREPARING METAL COMPLEX HYDRIDE NANORODS，申请号：PCT\/CN2013\/086220 (14\/380,662)，专利号：US**B2，申请日:2013.10.30，授权日期：2017.2.28，美国
\r[5] 刘永锋 庞越鹏 潘洪革 高明霞，一种制备金属配位氢化物纳米棒的方法，申请号：PCT\/CN2013\/086220，申请日:2013.10.30，授权日：2016.2.26(日本)
\r[6] 刘永锋，李由，高明霞，潘洪革，一种纳米颗粒状硼氢化物氨合物的制备方法，申请号：8.4，申请日: 2015.01.09，授权日：2016.6.1
\r[7] 刘永锋 马瑞军 潘洪革 高明霞, 一种首次库仑效率高的锂离子电池负极材料的制备方法, 申请号：8.4，申请日:2013.4.28，授权日：2016.2.24
\r[8] 刘永锋，张欣，高明霞，潘洪革，多孔碳负载纳米金属氧化物的催化剂及其制备方法以及储氢材料，专利号：ZL 4.2，申请日: 2014.05.22，授权日：2015.11.25
\r[9] 刘永锋 李超 潘洪革 高明霞，一种液相机械化学制备碱金属氢化物的方法，专利号：ZL 2.3，申请日:2013.5.15，授权日：2015.9.28
\r[10] 刘永锋，李瑞，潘洪革，贺燕萍，高明霞，一种多元硅基化合物的制备方法，专利号号：ZL 3.X，申请日：2012.7.30，授权日：2015.8.26
\r[11] 刘永锋 庞越鹏 潘洪革 高明霞，一种制备金属配位氢化物纳米棒的方法，专利号：ZL 8.6，申请日: 2013.8.2，授权日：2015.4.15
\r[12] 刘永锋 庞越鹏 潘洪革 高明霞，一种用于制备金属配位氢化物纳米棒的球磨罐，申请号：ZL 3.2，申请日:2013.8.2，授权日：2014.12.17
\r[13] 刘永锋，杨燕京，潘洪革，高明霞，一种硼氢化镁氨合物的固相合成方法，申请号：ZL 3.0，授权日：2014.5.14
\r[14] 刘永锋，庞越鹏，潘洪革，高明霞，一种亚微米棒状氢化铝镁的制备方法，专利号：6.5，授权日：2014.2.19
\r[15] 刘永锋，李超，潘洪革，高明霞，一种锂镁氮氢复合储氢材料，国家发明专利，专利号：7.9，授权日：2012.07.25
\r[16] 刘永锋，潘洪革，骆昆，高明霞，一种锂硼氮氢储氢材料，国家发明专利，专利号：4.6，授权日, 2010.12.1
\r[17] 高明霞 麦超 潘洪革 刘永锋，一种四氧化三铁\/碳复合材料及其制备方法和其在锂离子电池中的应用，申请号：ZL4.X，申请日：2014.2.21，授权日期：2016.8.17
\r[18] 高明霞，王军华，潘洪革，刘永锋，一种多孔三氧化二铁\/碳纳米片复合材料及其制备方法和其在制备锂离子电池中的应用，申请号：6.3，申请日: 2013.12.10，授权日：2016.6.15
\r[19] 潘洪革，李想，高明霞，刘永锋，一种锂硫电池的硫\/碳复合正极材料及其制备方法和应用，申请号：9.4，申请日:2013.04.16，授权日：2016.6.8
\r[20] 潘洪革，沈鲁恺，高明霞，刘永锋，一种基于羟基氧化钴的锂离子电池负极材料及其制备方法，专利号：ZL 9.0., 申请日：2012.8.17，授权日：2015.8.12
\r[21] 高明霞，王军华，潘洪革，刘永锋，一种基于氯化铁铵的锂离子电池负极材料及其制备方法和应用，专利号：ZL 3.3，申请日: 2013.05.21，授权日：2015.4.15
\r[22] 高明霞 丁继来 黄静露 潘洪革 刘永锋 徐钊君，一种泡沫铜氧化物\/铜锂离子电池负极及其制备方法，ZL 4.1，申请日：2011.11.30，授权日：2014.07.30
\r[23] 王白浪，高明霞，刘永锋，陈靖，冯冉，一种基于CuO的锂离子电池用复合负极材料及其制备方法和应用，申请号：ZL 1.8，授权日：2014.6.4
\r[24] 王白浪，高明霞，刘永锋，陈靖，冯冉，一种锂离子电池用的CuO\/Cu复合负极材料及其制备方法与应用，专利号：ZL 2.6，申请日：2012.4.25，授权日：2014.6.4
\r[25] 高明霞 潘洪革 叶欣 刘永锋，一种锂离子电池正极材料的制备方法，专利号：ZL 15.6，授权日：2013.06.26
\r[26] 高明霞 潘洪革 陈轩 刘永锋，高容量锂离子电池负极复合材料及其制备方法，专利号：5.6，授权日：2013.10.23
\r[27] 高明霞，朱丹，潘颐，潘洪革，刘永锋，巫红燕，一种SiC晶须强化的SiC陶瓷基复合材料及其制备方法，专利号：0.X，授权日：2013.2.6
\r[28] 高明霞，巫红燕，潘颐，潘洪革，刘永锋，朱丹，一种B4C\/SiC晶须\/SiC复相陶瓷基复合材料及其制备方法，专利号：0.3，授权日：2013.2.27
\r[29] 高明霞，顾坚，潘洪革，刘永锋，一种常温固相球磨合成硼氢化钙的方法，专利号：0.0，授权日：2012.12.19
\r[30] 潘洪革，刘永锋，钟凯，高明霞，一种Li-Mg-N-H储氢材料的制备方法，国家发明专利，专利号：8.5，授权日：2010.7.28
\r[31] 潘洪革，刘永锋，高明霞，雷永泉，贮氢合金的制备和淬火处理方法，国家发明专利，专利号：ZL**.3, 授权日：2006.1.4
\r[32] 潘洪革，刘永锋，高明霞，雷永泉，一种贮氢合金制备方法，国家发明专利，专利号：ZL**.X, 授权日：2006.1.4
\r[33] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用储氢合金制备和退火处理方法，国家发明专利，专利号：ZL**.1, 授权日：2006.1.4
\r[34] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用新型稀土系贮氢电极合金，国家发明专利，专利号：ZL**.6, 授权日：2004.10.27
\r[35] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用高容量长寿命型稀土系贮氢合金电极材料，国家发明专利，专利号：ZL**.1,授权日：2004.10.27
\r[36] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用新型混合稀土系贮氢电极合金，国家发明专利，专利号：ZL**.8, 授权日：2004.10.27
\r

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research_field
先进储氢材料；储氢器件；锂离子电池材料；材料电化学应用
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1
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2008-03-22 12:57:35
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selfintroduction
刘永锋，1977年10月生。浙江大学教授，博士生导师。国家基金委优秀青年基金获得者，国家“****”青年拔尖人才，教育部****奖励计划青年项目，浙江省****基金获得者。
\r
\r1995-1999 浙江大学 本科
\r2000-2005 浙江大学 博士(硕博连读，2009年获全国优秀博士学位论文提名)
\r2005-2007 National University of Singapore (新加坡国立大学) Research Fellow (博士后研究员)
\r2007-2012 浙江大学 副教授 (2011年入选浙江省钱江人才计划，浙江省151人才工程)
\r2011-2014 浙江大学 求是青年**** (2012年获国家优秀青年基金)
\r2011-至今 浙江大学 博士生导师
\r2012-至今 浙江大学 教授 (2015年入选国家“****”青年拔尖人才，教育部青年****，浙江省****基金)
\r
\r主要从事储氢材料和锂离子电池电极材料的设计、合成及其性能调控的基础理论和应用研究，在金属配位氢化物储氢材料的纳米化和性能调控、储氢电极合金新体系创制和高容量储锂材料可控制备等方面取得了一系列创新性成果。先后承担\/完成了来自于国家基金委、科技部、教育部、浙江省科技厅等科研项目15 项，申请发明专利53项，授权发明专利37项，包括国际PCT专利1项(日本)。在Nature Communications, Advanced Functional Materials, Journal of American Chemical Society, Energy & Environmental Science, Chemistry of Materials, Journal of Materials Chemistry等知名学术期刊上发表论文190余篇，其中170余篇被SCI 收录(第一\/通讯作者110余篇)，5篇论文被邀封面或封底展示；所发表论文被Web of Science收录的230种期刊的800位作者引用总计4000余次，其中他引3500余次。H 因子为35。应邀撰写综述论文3 篇，编译中文专著1本(储氢材料：储存性能表征，机械工业出版社，2013.10)，撰写英文专著Catalytic Batteries, Hydrogen Storage Materials, and Fuel Cells 中的一章(Chapter 13, Hydrogen Storage Materials, Elsvier出版社，2013.7)。
\r
\r2009 年获全国优秀博士论文提名奖；2010 年获浙江省自然科学学术奖二等奖，杭州市自然科学优秀学术成果二等奖；2011 年入选浙江省151 人才工程和“钱江人才”计划，获浙江省高校优秀科研成果一等奖，杭州市自然科学学术成果一等奖，杭州市青年科技奖；2012 年获国家优秀青年科学基金资助；2014年入选由Elsevier发布的2014年中国高被引****榜单(能源领域)；2015年入选国家****“青年拔尖人才”，教育部青年长江，获浙江省****基金。
\r
\r近5年代表性论文目录：
\r[1] Yun Cao, Yaxiong Yang, Zhuanghe Ren, Ni Jian, Mingxia Gao, Yongjun Wu, Min Zhu, Feng Pan, Yongfeng Liu,* and Hongge Pan, A New Strategy to Effectively Suppress the Initial Capacity Fading of Iron Oxides by Reacting with LiBH4, Adv. Funct. Mater., 2017, **.
\r[2] Yaxiong Yang, Yongfeng Liu*, Kaichao Pu, Xing Chen, He Tian, Mingxia Gao, Min Zhu, and Hongge Pan, Highly Stable Cycling of Amorphous Li2CO3-coated α-Fe2O3 Nanocrystallines Prepared via a New Mechanochemical Strategy for Li-ion Batteries, Adv. Funct. Mater., 2017,160511.
\r[3] Shiming Zhang, Haitao Gu, Hongge Pan,* Suhui Yang, Wubin Du, Xiang Li, Mingxia Gao, Yongfeng Liu,* Min Zhu, Liuzhang Ouyang, Dechao Jian, and Feng Pan, A Novel Strategy to Suppress Capacity and Voltage Fading of Li- and Mn-Rich Layered Oxide Cathode Material for Lithium-Ion Batteries, Adv. Energy Mater., 2016, **.
\r[4] Xin Zhang, Ruyan Wu, Zeyi Wang, Mingxia Gao, Hongge Pan and Yongfeng Liu*, Preparation and Catalytic Activity of a Novel Nanocrystalline ZrO2@C Composite for Hydrogen Storage in NaAlH4, Chem. Asian J., 2016,11, 3541-3549.
\r[5] Ruyan Wu, Hufei Du, Zeyi Wang, Mingxia Gao, Hongge Pan, Yongfeng Liu*, Remarkably improved hydrogen storage properties of NaAlH4 doped with 2D titanium carbide, J. Power Sources, 2016, 327, 519-525.
\r[6] You Li, Yongfeng Liu,* Xin Zhang, Di Zhou, Yunhao Lu, Mingxia Gao and Hongge Pan, An ultrasound-assisted wet-chemistry approach towards uniform Mg(BH4)2·6NH3 nanoparticles with improved dehydrogenation properties, J. Mater. Chem. A, 2016, 4, 8366–8373.
\r[7] Yongfeng Liu*, Yaxiong Yang, Mingxia Gao and Hongge Pan*, Tailoring Thermodynamics and Kinetics for Hydrogen Storage in Complex Hydrides towards Applications, Chemical Record, 2016, 16, 189-204.
\r[8] Yongfeng Liu, Xin Zhang, Ke Wang, Yaxiong Yang, Mingxia Gao, and Hongge Pan, Achieving Ambient Temperature Hydrogen Storage in Ultrafine Nanocrystalline TiO2@C-doped NaAlH4, J. Mater. Chem. A, 2016, 4, 1087–1095.
\r[9] Yongfeng Liu, Hufei Du, Xin Zhang, Yaxiong Yang, Mingxia Gao, Hongge Pan*, Superior catalytic activity derived from two-dimensional Ti3C2 precursor towards the hydrogen storage reaction of magnesium hydride, Chem. Commun., 2016, 52, 705-708
\r[10]Xin Zhang, Yongfeng Liu*, Ke Wang, You Li, Mingxia Gao, and Hongge Pan, Ultrafine Nanocrystalline CeO2@C-Containing NaAlH4 with Fast Kinetics and Good Reversibility for Hydrogen Storage, ChemSusChem, 2015, 8, 4180-4188.
\r[11]Yi Zhang, Yongfeng Liu*, Xin Zhang, You Li, Mingxia Gao, Hongge Pan, Synthesis of Nanosized Carbon Supported Ni Composite and Its Remarkable Catalysis for Hydrogen Desorption from the LiBH4-2LiNH2 System, J. Phys. Chem. C 2015, 119, 24760−24768.
\r[12]Yuepeng Pang, Yongfeng Liu*, Xin Zhang, Qian Li, Mingxia Gao, Hongge Pan, Composition-dependent reaction pathways and hydrogen storage properties of LiBH4\/Mg(AlH4)2 composites, Chem. Asian J., 2015, 10, 2452-2459.
\r[13]Yongfeng Liu, Yaxiong Yang, Xin Zhang, You Li, Mingxia Gao and Hongge Pan*, Insights into the dehydrogenation reaction process of a K containing Mg(NH2)2‐2LiH system, Dalton Trans., 2015, 44, 18012 –18018.
\r[14]Yi Zhang, Yongfeng Liu,* Xin Zhang, You Li, Mingxia Gao and Hongge Pan, Mechanistic understanding of the CoO-catalyzed hydrogen desorption from a LiBH4·NH3-3LiH system, Dalton Trans., 2015, 44, 14514 – 14522.
\r[15]Ruijun Ma, Yongfeng Liu,*, Yaxiong Yang, Kaichao Pu, Mingxia Gao, Hongge Pan, Li-Si-alloy-assisted improvement in the intrinsic cyclability of Mg2Si as an anode material for Li-ion batteries, Acta Mater., 2015, 98, 128-134
\r[16]Yanjing Yang, Yongfeng Liu*, You Li, Xin Zhang, Mingxia Gao and Hongge Pan*, Towards the endothermic dehydrogenation of nanoconfined magnesium borohydride ammoniate, J. Mater. Chem. A, 2015, 3, 11057-11065.
\r[17]Yongfeng Liu, Ping Yan, Ruijun Ma, Mingxia Gao, Hongge Pan*, Electrochemical properties of the ternary alloy Li5AlSi2 synthesized by reacting LiH, Al and Si as an anodic material for lithium-ion batteries, J. Power Sources, 2015, 283, 54-56.
\r[18]Xin Zhang, Yongfeng Liu*, Ke Wang, Mingxia Gao, and Hongge Pan, Remarkably Improved Hydrogen Storage Properties of Nanocrystalline TiO2-modified NaAlH4 and Evolution of Ti-containing Species during De-\/Hydrogenation, Nano Research, 2015, 8, 533-545.
\r[19]Yanjing Yang, Yongfeng Liu*, You Li, Mingxia Gao and Hongge Pan*, Fluorine-substituted Mg(BH4)2·2NH3 with improved dehydrogenation properties for hydrogen storage, J. Mater. Chem. A, 2015, 3, 570-578.
\r[20]Mingxia Gao, Dingsheng Wang, Xuqing Zhang, Hongge Pan,* Yongfeng Liu, Chu Liang, Congxiao Shang and Zhengxiao Guo, A hybrid Si@FeSiy\/SiOx anode structure for high performance lithium-ion batteries via ammonia-assisted one-pot synthesis, J. Mater. Chem. A, 2015, 3, 10767-10776.
\r[21]Ruijun Ma, Yongfeng Liu*, Yaxiong Yang, Mingxia Gao, Hongge Pan, Mg2Si anode for Li-ion batteries: Linking structural change to fast capacity fading, Appl. Phys. Lett., 2014 105, 213901.
\r[22]Chao Li, Yongfeng Liu*, Ruijun Ma, Xin Zhang, You Li, Mingxia Gao, and Hongge Pan, Superior Dehydrogenation\/Hydrogenation Kinetics and Long-Term Cycling Performance of K and Rb Cocatalyzed Mg(NH2)2 2LiH system, ACS Appl. Mater. Interfaces 2014, 6, 17024−17033.
\r[23]Yu Zhang, Yongfeng Liu*, Yuepeng Pang, Mingxia Gao and Hongge Pan, Role of Co3O4 in improving the hydrogen storage properties of a LiBH4-2LiNH2 composite, J. Mater. Chem. A, 2014, 2, 11155 – 11161.
\r[24]Yongfeng Liu, Ruijun Ma, Yanping He, Mingxia Gao and Hongge Pan*, Synthesis, Structure Transformation and Electrochemical Properties of Li2MgSi as a Novel Anode for Li-ion Batteries, Adv. Funct. Mater., 2014, 24, 3944-3952.
\r[25]Chao Li, Yongfeng Liu,* Yanjing Yang, Mingxia Gao and Hongge Pan*, High-temperature failure behaviour and mechanism of K-based additives in Li-Mg-N-H hydrogen storage systems, J. Mater. Chem. A, 2014, 2, 7345–7353
\r[26]Yuepeng Pang, Yongfeng Liu*, Mingxia Gao, Liuzhang Ouyang, Jiangwen Liu, Hui Wang, Min Zhu, Hongge Pan*, A mechanical-force-driven physical vapour deposition approach to fabricating complex hydride nanostructures, Nature Commun., 2014, 5, 3519.
\r[27]Ruijun Ma, Yongfeng Liu*, Ping Yan, Mingxia Gao, Hongge Pan*, A facile method for determining a suitable voltage window for an amorphous Li12Si7 anode, Electrochim. Acta, 2014, 129, 373-378
\r[28]Bo Li, Yongfeng Liu*, Chao Li, Mingxia Gao, and Hongge Pan, In situ formation of lithium fast-ion conductor and improved hydrogen desorption properties of LiNH2\/MgH2 system with the addition of lithium halides, J. Mater. Chem. A, 2014, 2, 3155-3162.
\r[29]Xin Zhang, Yongfeng Liu*, Yuepeng Pang, Mingxia Gao, and Hongge Pan, Significantly improved kinetics, reversibility and cycling stability for hydrogen storage in NaAlH4 with the Ti-incorporated metal organic framework MIL-125(Ti), J. Mater. Chem. A, 2014, 2, 1847–1854
\r[30]Chao Li, Yongfeng Liu*, Yuepeng Pang, Yingjie Gu, Mingxia Gao and Hongge Pan*, Compositional effects on the hydrogen storage properties of Mg(NH2)2–2LiH–xKH and the activity of KH during dehydrogenation reactions, Dalton Trans., 2014, 43, 2369–2377.
\r[31]Yanjing Yang, Yongfeng Liu*, Hui Wu, Wei Zhou, Mingxia Gao, and Hongge Pan*, An Ammonia-stabilized Mixed-cation Borohydride: Synthesis, Structure and Thermal Decomposition Behavior, Phys. Chem. Chem. Phys., 2014, 16 (1), 135 - 143.
\r[32]Chao Li, Yongfeng Liu*, Yingjie Gu, Mingxia Gao and Hongge Pan, Improved Hydrogen-Storage Thermodynamics and Kinetics for an RbF-Doped Mg(NH2)2–2 LiH System, Chem. Asian J. 2013, 8, 2136 – 2143.
\r[33]Mingxia Gao, Jian Gu, Hongge Pan, Yiliu Wang, Yongfeng Liu, Chu Liang and Zhengxiao Guo, Ca(BH4)2–LiBH4–MgH2: a novel ternary hydrogen storage system with superior long-term cycling performance, J. Mater. Chem. A, 2013, 1, 12285-12292.
\r[34]Yanjing Yang, Yongfeng Liu*, You Li, Mingxia Gao, and Hongge Pan, Heating Rate-Dependent Dehydrogenation in the Thermal Decomposition Process of Mg(BH4)2·6NH3, J. Phys. Chem. C, 2013, 117, 16326–16335.
\r[35]Jian Gu, Mingxia Gao, Hongge Pan, Yongfeng Liu, Bo Li, Yanjing Yang, Chu Liang, Hongliang Fu and Zhengxiao Guo, Improved hydrogen storage performance of Ca(BH4)2: a synergetic effect of porous morphology and in situ formed TiO2, Energy Environ. Sci., 2013, 6, 847–858.
\r[36]Chu Liang, Yongfeng Liu*, Mingxia Gao and Hongge Pan*, Understanding the role of K in the significantly improved hydrogen storage properties of a KOH-doped Li–Mg–N–H system, J. Mater. Chem. A, 2013, 1, 5031–5036.
\r[37]Hongge Pan*, Songbo Shi, Yongfeng Liu*, Bo Li, Yanjing Yang, Mingxia Gao, Improved hydrogen storage kinetics of the Li-Mg-N-H System by Addition of Mg(BH4)2, Dalton Trans., 2013, 42, 3802–3811
\r[38]Yanjing Yang, Yongfeng Liu*, You Li, Mingxia Gao, Hongge Pan, Synthesis and Thermal Decomposition Behaviors of Magnesium Borohydride Ammoniates with Controllable Composition as Hydrogen Storage Materials, Chem. Asian J. 2013, 8, 476 – 481
\r[39]Yongfeng Liu, Chao Li, Bo Li, Mingxia Gao, and Hongge Pan, Metathesis Reaction-Induced Significant Improvement in Hydrogen Storage Properties of the KF-Added Mg(NH2)2−2LiH System, J. Phys. Chem. C 2013, 117, 866−875
\r[40]Bo Li, Yongfeng Liu*, Jian Gu, Mingxia Gao, and Hongge Pan, Synergetic Effects of in Situ Formed CaH2 and LiBH4 on Hydrogen Storage Properties of the Li-Mg-N-H System, Chem. Asian J. 2013, 8, 374 – 384
\r[41]Ruijun Ma, Yongfeng Liu*, Yanping He, Mingxia Gao, and Hongge Pan*, Chemical Preinsertion of Lithium: An Approach to Improve the Intrinsic Capacity Retention of Bulk Si Anodes for Li-ion Batteries, J. Phys. Chem. Lett. 2012, 3, 3555−3558.
\r[42]Yongfeng Liu, Yanping He, Ruijun Ma, Mingxia Gao, Hongge Pan*, Improved lithium storage properties of Mg2Si anode material synthesized by hydrogen-driven chemical reaction, Electroch. Commun. 2012, 25, 15–18
\r[43]Bo Li, Yongfeng Liu*, Yu Zhang, Mingxia Gao, and Hongge Pan, Reaction Pathways for Hydrogen Uptake of the Li−Mg−N-Based Hydrogen Storage System, J. Phys. Chem. C 2012, 116, 13551−13558.
\r[44]YiFan Zhou, Yongfeng Liu*, Yu Zhang, Mingxia Gao, and Hongge Pan, Functions of MgH2 in hydrogen storage reactions of the 6LiBH4–CaH2 reactive hydride composite, Dalton Trans., 2012, 41, 10980-10987.
\r
\r授权国家发明专利：
\r[1] 刘永锋，杨亚雄，高明霞，潘洪革，一种硅氧碳复合锂离子电池负极材料的制备方法，申请号：4.0，申请日: 2015.01.09，授权日期：2017.5.17
\r[2] 刘永锋，杨亚雄，高明霞，潘洪革，一种多元多相复合锂离子电池负极材料的制备方法，申请号:8.8，申请日:2015.05.19，授权日期：2017.4.19
\r[3] 刘永锋，杨亚雄，高明霞，潘洪革，一种金属氧化物锂离子电池负极材料的制备方法，申请号：ZL8.2，申请日:2015.05.19，授权日期：2017.2.22
\r[4] 刘永锋 庞越鹏 潘洪革 高明霞，METHOD FOR PREPARING METAL COMPLEX HYDRIDE NANORODS，申请号：PCT\/CN2013\/086220 (14\/380,662)，专利号：US**B2，申请日:2013.10.30，授权日期：2017.2.28，美国
\r[5] 刘永锋 庞越鹏 潘洪革 高明霞，一种制备金属配位氢化物纳米棒的方法，申请号：PCT\/CN2013\/086220，申请日:2013.10.30，授权日：2016.2.26(日本)
\r[6] 刘永锋，李由，高明霞，潘洪革，一种纳米颗粒状硼氢化物氨合物的制备方法，申请号：8.4，申请日: 2015.01.09，授权日：2016.6.1
\r[7] 刘永锋 马瑞军 潘洪革 高明霞, 一种首次库仑效率高的锂离子电池负极材料的制备方法, 申请号：8.4，申请日:2013.4.28，授权日：2016.2.24
\r[8] 刘永锋，张欣，高明霞，潘洪革，多孔碳负载纳米金属氧化物的催化剂及其制备方法以及储氢材料，专利号：ZL 4.2，申请日: 2014.05.22，授权日：2015.11.25
\r[9] 刘永锋 李超 潘洪革 高明霞，一种液相机械化学制备碱金属氢化物的方法，专利号：ZL 2.3，申请日:2013.5.15，授权日：2015.9.28
\r[10] 刘永锋，李瑞，潘洪革，贺燕萍，高明霞，一种多元硅基化合物的制备方法，专利号号：ZL 3.X，申请日：2012.7.30，授权日：2015.8.26
\r[11] 刘永锋 庞越鹏 潘洪革 高明霞，一种制备金属配位氢化物纳米棒的方法，专利号：ZL 8.6，申请日: 2013.8.2，授权日：2015.4.15
\r[12] 刘永锋 庞越鹏 潘洪革 高明霞，一种用于制备金属配位氢化物纳米棒的球磨罐，申请号：ZL 3.2，申请日:2013.8.2，授权日：2014.12.17
\r[13] 刘永锋，杨燕京，潘洪革，高明霞，一种硼氢化镁氨合物的固相合成方法，申请号：ZL 3.0，授权日：2014.5.14
\r[14] 刘永锋，庞越鹏，潘洪革，高明霞，一种亚微米棒状氢化铝镁的制备方法，专利号：6.5，授权日：2014.2.19
\r[15] 刘永锋，李超，潘洪革，高明霞，一种锂镁氮氢复合储氢材料，国家发明专利，专利号：7.9，授权日：2012.07.25
\r[16] 刘永锋，潘洪革，骆昆，高明霞，一种锂硼氮氢储氢材料，国家发明专利，专利号：4.6，授权日, 2010.12.1
\r[17] 高明霞 麦超 潘洪革 刘永锋，一种四氧化三铁\/碳复合材料及其制备方法和其在锂离子电池中的应用，申请号：ZL4.X，申请日：2014.2.21，授权日期：2016.8.17
\r[18] 高明霞，王军华，潘洪革，刘永锋，一种多孔三氧化二铁\/碳纳米片复合材料及其制备方法和其在制备锂离子电池中的应用，申请号：6.3，申请日: 2013.12.10，授权日：2016.6.15
\r[19] 潘洪革，李想，高明霞，刘永锋，一种锂硫电池的硫\/碳复合正极材料及其制备方法和应用，申请号：9.4，申请日:2013.04.16，授权日：2016.6.8
\r[20] 潘洪革，沈鲁恺，高明霞，刘永锋，一种基于羟基氧化钴的锂离子电池负极材料及其制备方法，专利号：ZL 9.0., 申请日：2012.8.17，授权日：2015.8.12
\r[21] 高明霞，王军华，潘洪革，刘永锋，一种基于氯化铁铵的锂离子电池负极材料及其制备方法和应用，专利号：ZL 3.3，申请日: 2013.05.21，授权日：2015.4.15
\r[22] 高明霞 丁继来 黄静露 潘洪革 刘永锋 徐钊君，一种泡沫铜氧化物\/铜锂离子电池负极及其制备方法，ZL 4.1，申请日：2011.11.30，授权日：2014.07.30
\r[23] 王白浪，高明霞，刘永锋，陈靖，冯冉，一种基于CuO的锂离子电池用复合负极材料及其制备方法和应用，申请号：ZL 1.8，授权日：2014.6.4
\r[24] 王白浪，高明霞，刘永锋，陈靖，冯冉，一种锂离子电池用的CuO\/Cu复合负极材料及其制备方法与应用，专利号：ZL 2.6，申请日：2012.4.25，授权日：2014.6.4
\r[25] 高明霞 潘洪革 叶欣 刘永锋，一种锂离子电池正极材料的制备方法，专利号：ZL 15.6，授权日：2013.06.26
\r[26] 高明霞 潘洪革 陈轩 刘永锋，高容量锂离子电池负极复合材料及其制备方法，专利号：5.6，授权日：2013.10.23
\r[27] 高明霞，朱丹，潘颐，潘洪革，刘永锋，巫红燕，一种SiC晶须强化的SiC陶瓷基复合材料及其制备方法，专利号：0.X，授权日：2013.2.6
\r[28] 高明霞，巫红燕，潘颐，潘洪革，刘永锋，朱丹，一种B4C\/SiC晶须\/SiC复相陶瓷基复合材料及其制备方法，专利号：0.3，授权日：2013.2.27
\r[29] 高明霞，顾坚，潘洪革，刘永锋，一种常温固相球磨合成硼氢化钙的方法，专利号：0.0，授权日：2012.12.19
\r[30] 潘洪革，刘永锋，钟凯，高明霞，一种Li-Mg-N-H储氢材料的制备方法，国家发明专利，专利号：8.5，授权日：2010.7.28
\r[31] 潘洪革，刘永锋，高明霞，雷永泉，贮氢合金的制备和淬火处理方法，国家发明专利，专利号：ZL**.3, 授权日：2006.1.4
\r[32] 潘洪革，刘永锋，高明霞，雷永泉，一种贮氢合金制备方法，国家发明专利，专利号：ZL**.X, 授权日：2006.1.4
\r[33] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用储氢合金制备和退火处理方法，国家发明专利，专利号：ZL**.1, 授权日：2006.1.4
\r[34] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用新型稀土系贮氢电极合金，国家发明专利，专利号：ZL**.6, 授权日：2004.10.27
\r[35] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用高容量长寿命型稀土系贮氢合金电极材料，国家发明专利，专利号：ZL**.1,授权日：2004.10.27
\r[36] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用新型混合稀土系贮氢电极合金，国家发明专利，专利号：ZL**.8, 授权日：2004.10.27
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刘永锋，1977年10月生。浙江大学教授，博士生导师。国家基金委优秀青年基金获得者，国家“****”青年拔尖人才，教育部****奖励计划青年项目，浙江省****基金获得者。
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\r1995-1999 浙江大学 本科
\r2000-2005 浙江大学 博士(硕博连读，2009年获全国优秀博士学位论文提名)
\r2005-2007 National University of Singapore (新加坡国立大学) Research Fellow (博士后研究员)
\r2007-2012 浙江大学 副教授 (2011年入选浙江省钱江人才计划，浙江省151人才工程)
\r2011-2014 浙江大学 求是青年**** (2012年获国家优秀青年基金)
\r2011-至今 浙江大学 博士生导师
\r2012-至今 浙江大学 教授 (2015年入选国家“****”青年拔尖人才，教育部青年****，浙江省****基金)
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\r主要从事储氢材料和锂离子电池电极材料的设计、合成及其性能调控的基础理论和应用研究，在金属配位氢化物储氢材料的纳米化和性能调控、储氢电极合金新体系创制和高容量储锂材料可控制备等方面取得了一系列创新性成果。先后承担\/完成了来自于国家基金委、科技部、教育部、浙江省科技厅等科研项目15 项，申请发明专利53项，授权发明专利37项，包括国际PCT专利1项(日本)。在Nature Communications, Advanced Functional Materials, Journal of American Chemical Society, Energy & Environmental Science, Chemistry of Materials, Journal of Materials Chemistry等知名学术期刊上发表论文190余篇，其中170余篇被SCI 收录(第一\/通讯作者110余篇)，5篇论文被邀封面或封底展示；所发表论文被Web of Science收录的230种期刊的800位作者引用总计4000余次，其中他引3500余次。H 因子为35。应邀撰写综述论文3 篇，编译中文专著1本(储氢材料：储存性能表征，机械工业出版社，2013.10)，撰写英文专著Catalytic Batteries, Hydrogen Storage Materials, and Fuel Cells 中的一章(Chapter 13, Hydrogen Storage Materials, Elsvier出版社，2013.7)。
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\r2009 年获全国优秀博士论文提名奖；2010 年获浙江省自然科学学术奖二等奖，杭州市自然科学优秀学术成果二等奖；2011 年入选浙江省151 人才工程和“钱江人才”计划，获浙江省高校优秀科研成果一等奖，杭州市自然科学学术成果一等奖，杭州市青年科技奖；2012 年获国家优秀青年科学基金资助；2014年入选由Elsevier发布的2014年中国高被引****榜单(能源领域)；2015年入选国家****“青年拔尖人才”，教育部青年长江，获浙江省****基金。
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\r近5年代表性论文目录：
\r[1] Yun Cao, Yaxiong Yang, Zhuanghe Ren, Ni Jian, Mingxia Gao, Yongjun Wu, Min Zhu, Feng Pan, Yongfeng Liu,* and Hongge Pan, A New Strategy to Effectively Suppress the Initial Capacity Fading of Iron Oxides by Reacting with LiBH4, Adv. Funct. Mater., 2017, **.
\r[2] Yaxiong Yang, Yongfeng Liu*, Kaichao Pu, Xing Chen, He Tian, Mingxia Gao, Min Zhu, and Hongge Pan, Highly Stable Cycling of Amorphous Li2CO3-coated α-Fe2O3 Nanocrystallines Prepared via a New Mechanochemical Strategy for Li-ion Batteries, Adv. Funct. Mater., 2017,160511.
\r[3] Shiming Zhang, Haitao Gu, Hongge Pan,* Suhui Yang, Wubin Du, Xiang Li, Mingxia Gao, Yongfeng Liu,* Min Zhu, Liuzhang Ouyang, Dechao Jian, and Feng Pan, A Novel Strategy to Suppress Capacity and Voltage Fading of Li- and Mn-Rich Layered Oxide Cathode Material for Lithium-Ion Batteries, Adv. Energy Mater., 2016, **.
\r[4] Xin Zhang, Ruyan Wu, Zeyi Wang, Mingxia Gao, Hongge Pan and Yongfeng Liu*, Preparation and Catalytic Activity of a Novel Nanocrystalline ZrO2@C Composite for Hydrogen Storage in NaAlH4, Chem. Asian J., 2016,11, 3541-3549.
\r[5] Ruyan Wu, Hufei Du, Zeyi Wang, Mingxia Gao, Hongge Pan, Yongfeng Liu*, Remarkably improved hydrogen storage properties of NaAlH4 doped with 2D titanium carbide, J. Power Sources, 2016, 327, 519-525.
\r[6] You Li, Yongfeng Liu,* Xin Zhang, Di Zhou, Yunhao Lu, Mingxia Gao and Hongge Pan, An ultrasound-assisted wet-chemistry approach towards uniform Mg(BH4)2·6NH3 nanoparticles with improved dehydrogenation properties, J. Mater. Chem. A, 2016, 4, 8366–8373.
\r[7] Yongfeng Liu*, Yaxiong Yang, Mingxia Gao and Hongge Pan*, Tailoring Thermodynamics and Kinetics for Hydrogen Storage in Complex Hydrides towards Applications, Chemical Record, 2016, 16, 189-204.
\r[8] Yongfeng Liu, Xin Zhang, Ke Wang, Yaxiong Yang, Mingxia Gao, and Hongge Pan, Achieving Ambient Temperature Hydrogen Storage in Ultrafine Nanocrystalline TiO2@C-doped NaAlH4, J. Mater. Chem. A, 2016, 4, 1087–1095.
\r[9] Yongfeng Liu, Hufei Du, Xin Zhang, Yaxiong Yang, Mingxia Gao, Hongge Pan*, Superior catalytic activity derived from two-dimensional Ti3C2 precursor towards the hydrogen storage reaction of magnesium hydride, Chem. Commun., 2016, 52, 705-708
\r[10]Xin Zhang, Yongfeng Liu*, Ke Wang, You Li, Mingxia Gao, and Hongge Pan, Ultrafine Nanocrystalline CeO2@C-Containing NaAlH4 with Fast Kinetics and Good Reversibility for Hydrogen Storage, ChemSusChem, 2015, 8, 4180-4188.
\r[11]Yi Zhang, Yongfeng Liu*, Xin Zhang, You Li, Mingxia Gao, Hongge Pan, Synthesis of Nanosized Carbon Supported Ni Composite and Its Remarkable Catalysis for Hydrogen Desorption from the LiBH4-2LiNH2 System, J. Phys. Chem. C 2015, 119, 24760−24768.
\r[12]Yuepeng Pang, Yongfeng Liu*, Xin Zhang, Qian Li, Mingxia Gao, Hongge Pan, Composition-dependent reaction pathways and hydrogen storage properties of LiBH4\/Mg(AlH4)2 composites, Chem. Asian J., 2015, 10, 2452-2459.
\r[13]Yongfeng Liu, Yaxiong Yang, Xin Zhang, You Li, Mingxia Gao and Hongge Pan*, Insights into the dehydrogenation reaction process of a K containing Mg(NH2)2‐2LiH system, Dalton Trans., 2015, 44, 18012 –18018.
\r[14]Yi Zhang, Yongfeng Liu,* Xin Zhang, You Li, Mingxia Gao and Hongge Pan, Mechanistic understanding of the CoO-catalyzed hydrogen desorption from a LiBH4·NH3-3LiH system, Dalton Trans., 2015, 44, 14514 – 14522.
\r[15]Ruijun Ma, Yongfeng Liu,*, Yaxiong Yang, Kaichao Pu, Mingxia Gao, Hongge Pan, Li-Si-alloy-assisted improvement in the intrinsic cyclability of Mg2Si as an anode material for Li-ion batteries, Acta Mater., 2015, 98, 128-134
\r[16]Yanjing Yang, Yongfeng Liu*, You Li, Xin Zhang, Mingxia Gao and Hongge Pan*, Towards the endothermic dehydrogenation of nanoconfined magnesium borohydride ammoniate, J. Mater. Chem. A, 2015, 3, 11057-11065.
\r[17]Yongfeng Liu, Ping Yan, Ruijun Ma, Mingxia Gao, Hongge Pan*, Electrochemical properties of the ternary alloy Li5AlSi2 synthesized by reacting LiH, Al and Si as an anodic material for lithium-ion batteries, J. Power Sources, 2015, 283, 54-56.
\r[18]Xin Zhang, Yongfeng Liu*, Ke Wang, Mingxia Gao, and Hongge Pan, Remarkably Improved Hydrogen Storage Properties of Nanocrystalline TiO2-modified NaAlH4 and Evolution of Ti-containing Species during De-\/Hydrogenation, Nano Research, 2015, 8, 533-545.
\r[19]Yanjing Yang, Yongfeng Liu*, You Li, Mingxia Gao and Hongge Pan*, Fluorine-substituted Mg(BH4)2·2NH3 with improved dehydrogenation properties for hydrogen storage, J. Mater. Chem. A, 2015, 3, 570-578.
\r[20]Mingxia Gao, Dingsheng Wang, Xuqing Zhang, Hongge Pan,* Yongfeng Liu, Chu Liang, Congxiao Shang and Zhengxiao Guo, A hybrid Si@FeSiy\/SiOx anode structure for high performance lithium-ion batteries via ammonia-assisted one-pot synthesis, J. Mater. Chem. A, 2015, 3, 10767-10776.
\r[21]Ruijun Ma, Yongfeng Liu*, Yaxiong Yang, Mingxia Gao, Hongge Pan, Mg2Si anode for Li-ion batteries: Linking structural change to fast capacity fading, Appl. Phys. Lett., 2014 105, 213901.
\r[22]Chao Li, Yongfeng Liu*, Ruijun Ma, Xin Zhang, You Li, Mingxia Gao, and Hongge Pan, Superior Dehydrogenation\/Hydrogenation Kinetics and Long-Term Cycling Performance of K and Rb Cocatalyzed Mg(NH2)2 2LiH system, ACS Appl. Mater. Interfaces 2014, 6, 17024−17033.
\r[23]Yu Zhang, Yongfeng Liu*, Yuepeng Pang, Mingxia Gao and Hongge Pan, Role of Co3O4 in improving the hydrogen storage properties of a LiBH4-2LiNH2 composite, J. Mater. Chem. A, 2014, 2, 11155 – 11161.
\r[24]Yongfeng Liu, Ruijun Ma, Yanping He, Mingxia Gao and Hongge Pan*, Synthesis, Structure Transformation and Electrochemical Properties of Li2MgSi as a Novel Anode for Li-ion Batteries, Adv. Funct. Mater., 2014, 24, 3944-3952.
\r[25]Chao Li, Yongfeng Liu,* Yanjing Yang, Mingxia Gao and Hongge Pan*, High-temperature failure behaviour and mechanism of K-based additives in Li-Mg-N-H hydrogen storage systems, J. Mater. Chem. A, 2014, 2, 7345–7353
\r[26]Yuepeng Pang, Yongfeng Liu*, Mingxia Gao, Liuzhang Ouyang, Jiangwen Liu, Hui Wang, Min Zhu, Hongge Pan*, A mechanical-force-driven physical vapour deposition approach to fabricating complex hydride nanostructures, Nature Commun., 2014, 5, 3519.
\r[27]Ruijun Ma, Yongfeng Liu*, Ping Yan, Mingxia Gao, Hongge Pan*, A facile method for determining a suitable voltage window for an amorphous Li12Si7 anode, Electrochim. Acta, 2014, 129, 373-378
\r[28]Bo Li, Yongfeng Liu*, Chao Li, Mingxia Gao, and Hongge Pan, In situ formation of lithium fast-ion conductor and improved hydrogen desorption properties of LiNH2\/MgH2 system with the addition of lithium halides, J. Mater. Chem. A, 2014, 2, 3155-3162.
\r[29]Xin Zhang, Yongfeng Liu*, Yuepeng Pang, Mingxia Gao, and Hongge Pan, Significantly improved kinetics, reversibility and cycling stability for hydrogen storage in NaAlH4 with the Ti-incorporated metal organic framework MIL-125(Ti), J. Mater. Chem. A, 2014, 2, 1847–1854
\r[30]Chao Li, Yongfeng Liu*, Yuepeng Pang, Yingjie Gu, Mingxia Gao and Hongge Pan*, Compositional effects on the hydrogen storage properties of Mg(NH2)2–2LiH–xKH and the activity of KH during dehydrogenation reactions, Dalton Trans., 2014, 43, 2369–2377.
\r[31]Yanjing Yang, Yongfeng Liu*, Hui Wu, Wei Zhou, Mingxia Gao, and Hongge Pan*, An Ammonia-stabilized Mixed-cation Borohydride: Synthesis, Structure and Thermal Decomposition Behavior, Phys. Chem. Chem. Phys., 2014, 16 (1), 135 - 143.
\r[32]Chao Li, Yongfeng Liu*, Yingjie Gu, Mingxia Gao and Hongge Pan, Improved Hydrogen-Storage Thermodynamics and Kinetics for an RbF-Doped Mg(NH2)2–2 LiH System, Chem. Asian J. 2013, 8, 2136 – 2143.
\r[33]Mingxia Gao, Jian Gu, Hongge Pan, Yiliu Wang, Yongfeng Liu, Chu Liang and Zhengxiao Guo, Ca(BH4)2–LiBH4–MgH2: a novel ternary hydrogen storage system with superior long-term cycling performance, J. Mater. Chem. A, 2013, 1, 12285-12292.
\r[34]Yanjing Yang, Yongfeng Liu*, You Li, Mingxia Gao, and Hongge Pan, Heating Rate-Dependent Dehydrogenation in the Thermal Decomposition Process of Mg(BH4)2·6NH3, J. Phys. Chem. C, 2013, 117, 16326–16335.
\r[35]Jian Gu, Mingxia Gao, Hongge Pan, Yongfeng Liu, Bo Li, Yanjing Yang, Chu Liang, Hongliang Fu and Zhengxiao Guo, Improved hydrogen storage performance of Ca(BH4)2: a synergetic effect of porous morphology and in situ formed TiO2, Energy Environ. Sci., 2013, 6, 847–858.
\r[36]Chu Liang, Yongfeng Liu*, Mingxia Gao and Hongge Pan*, Understanding the role of K in the significantly improved hydrogen storage properties of a KOH-doped Li–Mg–N–H system, J. Mater. Chem. A, 2013, 1, 5031–5036.
\r[37]Hongge Pan*, Songbo Shi, Yongfeng Liu*, Bo Li, Yanjing Yang, Mingxia Gao, Improved hydrogen storage kinetics of the Li-Mg-N-H System by Addition of Mg(BH4)2, Dalton Trans., 2013, 42, 3802–3811
\r[38]Yanjing Yang, Yongfeng Liu*, You Li, Mingxia Gao, Hongge Pan, Synthesis and Thermal Decomposition Behaviors of Magnesium Borohydride Ammoniates with Controllable Composition as Hydrogen Storage Materials, Chem. Asian J. 2013, 8, 476 – 481
\r[39]Yongfeng Liu, Chao Li, Bo Li, Mingxia Gao, and Hongge Pan, Metathesis Reaction-Induced Significant Improvement in Hydrogen Storage Properties of the KF-Added Mg(NH2)2−2LiH System, J. Phys. Chem. C 2013, 117, 866−875
\r[40]Bo Li, Yongfeng Liu*, Jian Gu, Mingxia Gao, and Hongge Pan, Synergetic Effects of in Situ Formed CaH2 and LiBH4 on Hydrogen Storage Properties of the Li-Mg-N-H System, Chem. Asian J. 2013, 8, 374 – 384
\r[41]Ruijun Ma, Yongfeng Liu*, Yanping He, Mingxia Gao, and Hongge Pan*, Chemical Preinsertion of Lithium: An Approach to Improve the Intrinsic Capacity Retention of Bulk Si Anodes for Li-ion Batteries, J. Phys. Chem. Lett. 2012, 3, 3555−3558.
\r[42]Yongfeng Liu, Yanping He, Ruijun Ma, Mingxia Gao, Hongge Pan*, Improved lithium storage properties of Mg2Si anode material synthesized by hydrogen-driven chemical reaction, Electroch. Commun. 2012, 25, 15–18
\r[43]Bo Li, Yongfeng Liu*, Yu Zhang, Mingxia Gao, and Hongge Pan, Reaction Pathways for Hydrogen Uptake of the Li−Mg−N-Based Hydrogen Storage System, J. Phys. Chem. C 2012, 116, 13551−13558.
\r[44]YiFan Zhou, Yongfeng Liu*, Yu Zhang, Mingxia Gao, and Hongge Pan, Functions of MgH2 in hydrogen storage reactions of the 6LiBH4–CaH2 reactive hydride composite, Dalton Trans., 2012, 41, 10980-10987.
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\r授权国家发明专利：
\r[1] 刘永锋，杨亚雄，高明霞，潘洪革，一种硅氧碳复合锂离子电池负极材料的制备方法，申请号：4.0，申请日: 2015.01.09，授权日期：2017.5.17
\r[2] 刘永锋，杨亚雄，高明霞，潘洪革，一种多元多相复合锂离子电池负极材料的制备方法，申请号:8.8，申请日:2015.05.19，授权日期：2017.4.19
\r[3] 刘永锋，杨亚雄，高明霞，潘洪革，一种金属氧化物锂离子电池负极材料的制备方法，申请号：ZL8.2，申请日:2015.05.19，授权日期：2017.2.22
\r[4] 刘永锋 庞越鹏 潘洪革 高明霞，METHOD FOR PREPARING METAL COMPLEX HYDRIDE NANORODS，申请号：PCT\/CN2013\/086220 (14\/380,662)，专利号：US**B2，申请日:2013.10.30，授权日期：2017.2.28，美国
\r[5] 刘永锋 庞越鹏 潘洪革 高明霞，一种制备金属配位氢化物纳米棒的方法，申请号：PCT\/CN2013\/086220，申请日:2013.10.30，授权日：2016.2.26(日本)
\r[6] 刘永锋，李由，高明霞，潘洪革，一种纳米颗粒状硼氢化物氨合物的制备方法，申请号：8.4，申请日: 2015.01.09，授权日：2016.6.1
\r[7] 刘永锋 马瑞军 潘洪革 高明霞, 一种首次库仑效率高的锂离子电池负极材料的制备方法, 申请号：8.4，申请日:2013.4.28，授权日：2016.2.24
\r[8] 刘永锋，张欣，高明霞，潘洪革，多孔碳负载纳米金属氧化物的催化剂及其制备方法以及储氢材料，专利号：ZL 4.2，申请日: 2014.05.22，授权日：2015.11.25
\r[9] 刘永锋 李超 潘洪革 高明霞，一种液相机械化学制备碱金属氢化物的方法，专利号：ZL 2.3，申请日:2013.5.15，授权日：2015.9.28
\r[10] 刘永锋，李瑞，潘洪革，贺燕萍，高明霞，一种多元硅基化合物的制备方法，专利号号：ZL 3.X，申请日：2012.7.30，授权日：2015.8.26
\r[11] 刘永锋 庞越鹏 潘洪革 高明霞，一种制备金属配位氢化物纳米棒的方法，专利号：ZL 8.6，申请日: 2013.8.2，授权日：2015.4.15
\r[12] 刘永锋 庞越鹏 潘洪革 高明霞，一种用于制备金属配位氢化物纳米棒的球磨罐，申请号：ZL 3.2，申请日:2013.8.2，授权日：2014.12.17
\r[13] 刘永锋，杨燕京，潘洪革，高明霞，一种硼氢化镁氨合物的固相合成方法，申请号：ZL 3.0，授权日：2014.5.14
\r[14] 刘永锋，庞越鹏，潘洪革，高明霞，一种亚微米棒状氢化铝镁的制备方法，专利号：6.5，授权日：2014.2.19
\r[15] 刘永锋，李超，潘洪革，高明霞，一种锂镁氮氢复合储氢材料，国家发明专利，专利号：7.9，授权日：2012.07.25
\r[16] 刘永锋，潘洪革，骆昆，高明霞，一种锂硼氮氢储氢材料，国家发明专利，专利号：4.6，授权日, 2010.12.1
\r[17] 高明霞 麦超 潘洪革 刘永锋，一种四氧化三铁\/碳复合材料及其制备方法和其在锂离子电池中的应用，申请号：ZL4.X，申请日：2014.2.21，授权日期：2016.8.17
\r[18] 高明霞，王军华，潘洪革，刘永锋，一种多孔三氧化二铁\/碳纳米片复合材料及其制备方法和其在制备锂离子电池中的应用，申请号：6.3，申请日: 2013.12.10，授权日：2016.6.15
\r[19] 潘洪革，李想，高明霞，刘永锋，一种锂硫电池的硫\/碳复合正极材料及其制备方法和应用，申请号：9.4，申请日:2013.04.16，授权日：2016.6.8
\r[20] 潘洪革，沈鲁恺，高明霞，刘永锋，一种基于羟基氧化钴的锂离子电池负极材料及其制备方法，专利号：ZL 9.0., 申请日：2012.8.17，授权日：2015.8.12
\r[21] 高明霞，王军华，潘洪革，刘永锋，一种基于氯化铁铵的锂离子电池负极材料及其制备方法和应用，专利号：ZL 3.3，申请日: 2013.05.21，授权日：2015.4.15
\r[22] 高明霞 丁继来 黄静露 潘洪革 刘永锋 徐钊君，一种泡沫铜氧化物\/铜锂离子电池负极及其制备方法，ZL 4.1，申请日：2011.11.30，授权日：2014.07.30
\r[23] 王白浪，高明霞，刘永锋，陈靖，冯冉，一种基于CuO的锂离子电池用复合负极材料及其制备方法和应用，申请号：ZL 1.8，授权日：2014.6.4
\r[24] 王白浪，高明霞，刘永锋，陈靖，冯冉，一种锂离子电池用的CuO\/Cu复合负极材料及其制备方法与应用，专利号：ZL 2.6，申请日：2012.4.25，授权日：2014.6.4
\r[25] 高明霞 潘洪革 叶欣 刘永锋，一种锂离子电池正极材料的制备方法，专利号：ZL 15.6，授权日：2013.06.26
\r[26] 高明霞 潘洪革 陈轩 刘永锋，高容量锂离子电池负极复合材料及其制备方法，专利号：5.6，授权日：2013.10.23
\r[27] 高明霞，朱丹，潘颐，潘洪革，刘永锋，巫红燕，一种SiC晶须强化的SiC陶瓷基复合材料及其制备方法，专利号：0.X，授权日：2013.2.6
\r[28] 高明霞，巫红燕，潘颐，潘洪革，刘永锋，朱丹，一种B4C\/SiC晶须\/SiC复相陶瓷基复合材料及其制备方法，专利号：0.3，授权日：2013.2.27
\r[29] 高明霞，顾坚，潘洪革，刘永锋，一种常温固相球磨合成硼氢化钙的方法，专利号：0.0，授权日：2012.12.19
\r[30] 潘洪革，刘永锋，钟凯，高明霞，一种Li-Mg-N-H储氢材料的制备方法，国家发明专利，专利号：8.5，授权日：2010.7.28
\r[31] 潘洪革，刘永锋，高明霞，雷永泉，贮氢合金的制备和淬火处理方法，国家发明专利，专利号：ZL**.3, 授权日：2006.1.4
\r[32] 潘洪革，刘永锋，高明霞，雷永泉，一种贮氢合金制备方法，国家发明专利，专利号：ZL**.X, 授权日：2006.1.4
\r[33] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用储氢合金制备和退火处理方法，国家发明专利，专利号：ZL**.1, 授权日：2006.1.4
\r[34] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用新型稀土系贮氢电极合金，国家发明专利，专利号：ZL**.6, 授权日：2004.10.27
\r[35] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用高容量长寿命型稀土系贮氢合金电极材料，国家发明专利，专利号：ZL**.1,授权日：2004.10.27
\r[36] 潘洪革，刘永锋，高明霞，雷永泉，镍－金属氢化物二次电池用新型混合稀土系贮氢电极合金，国家发明专利，专利号：ZL**.8, 授权日：2004.10.27
\r

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