罗浩,博士,副教授,硕士生导师,入选2025年度全球前2%顶尖科学家榜单,被评为福建省/厦门市引进高层次人才。2021年4月博士毕业于哈尔滨工业大学电化学工程专业,从事新能源材料与器件领域的基础及应用研究。主持承担国家自然科学基金青年项目、中国博士后科学基金特别资助项目、福建省自然科学基金面上项目等科研项目10余项;申请发明专利8项。与阿德莱德大学、复旦大学、浙江大学、哈尔滨工业大学等国内外优秀科研团队长期合作。以第一/通讯作者在Matter(Cell子刊)、PNAS(美国国家科学院院刊)、Adv. Mater.、Adv. Energy Mater.、Adv. Funct. Mater.(2篇)、ACS Nano、Chem. Sci.、Nano-Micro Lett.、Nano Energy (2篇)、Energy Storage Mater. (4篇)、J. Energy Chem.(4篇)、Nano Res.、Rare Met. (2篇)、J. Colloid Interf. Sci. (4篇)、Sep. Purif. Technol.等中科院一区SCI期刊上发表论文30余篇,多篇论文入选ESI热点/高被引论文;他引次数2200余次,h因子24。讲授《锂离子电池原理与工艺》、《有机化学》、《科学研究方法与学术论文写作》、《材料制备技术综合实验》等本科生课程。指导本科生获批多项省级、校级大学生创新创业项目。主持本科生教研教改项目1项。
工作经历:
2023.08-至今 2026年世界杯奖杯官网 副教授/硕士生导师
2021.07-2023.07 郑州大学2026年世界杯官网 直聘副教授/硕士生导师
2023.04-2023.06 复旦大学水系电池研究中心 访问学者
主要研究领域:
[1] 锂/钠离子电池(正负极材料设计制备及新型电解液开发)
[2] 电池回收、安全及失效分析(产热、产气,力学特性等)
[3] 水系电池(锌/铁/锰离子电池、卤素电池、碱性二次电池等)
[4] 固态电池
[5] DFT理论计算、MD模拟、AI机器学习等
招生信息:
常年招收具有材料、化工、化学、物理及电子信息等相关专业背景的研究生!欢迎有志于从事新能源材料与器件研究的本科生和研究生加入团队。近三年每年招生名额3名。指导的研究生获得硕士生国家奖学金5人次,优秀硕士毕业生5人次,已毕业学生去向西安交通大学(Ph.D)、北京化工大学(Ph.D)及企事业单位等。
有意向的同学直接发邮箱联系: luohao_hit@163.com;luohao@xmut.edu.cn
近年三年承担的主要科研项目:
[1] 国家自然科学基金青年项目,2026-2029,30万,项目负责人,在研
[2] 福建省自然科学基金面上项目,2024-2027,10万,项目负责人,在研
[3] 厦门理工学院高层次人才启动项目,2024-2027,15万,项目负责人,在研
[4] 厦门市科技计划项目-重大项目,2024-2026,100万,参与人,在研
[5] 中国博士后科学基金特别资助(站前),2022-2024,18万,项目负责人
[6] 河南省重点研发与推广专项攻关项目,2022-2023,10万,项目负责人
[7] 教育部重点实验室开放基金,2024-2026,3万,项目负责人
[8] 郑州大学“求是计划”科研专项,2022-2024,12万,项目负责人
主要奖励:
[1] 全球前2%顶尖科学家,2025年
[2] 福建省高层次人次C类,2024年
[3] 厦门市高层次人次C类,2024年
[4] 哈尔滨工业大学优秀硕士/博士毕业生,2017/2021年
学术兼职:
[1]《Rare Metals》等中科院一区SCI杂志青年编委
[2] Nature子刊等多个SCI杂志审稿人
[3] 中国材料研究学会高级会员、中国化学会会员
[4] 福建省引进高层次创业创新人才协会会员
[5] 厦门市智能制造产教融合实训基地专家指导委员会,专家组成员
近年来发表的代表性学术论著(仅列出中科院一区论文):
[1] Hao Luo*, Dongliang Chao* et al. Aqueous Manganese-Ion Batteries: The Past, Present, and Future. Matter, 2025, 102379.(Cell子刊;第一作者&共同通讯作者)
[2] Lanfang Que, Hao Luo*, Dongliang Chao* et al. Unveil the Origin of Voltage Oscillation for Sodium-Ion Batteries Operating at −40 ℃. Proceedings of the National Academy of Sciences of the United States of America (PNAS), 2024, 121(17): e2311075121. (美国国家科学院院刊,IF=11.1,共同通讯作者)
[3] Hao Luo*, Mi Lu*, Tiefeng Liu* et al. Aqueous Iron-Ions Batteries: Status, Solutions, and Prospects. Advanced Materials, 2025, 2507978.(IF=26.8,第一作者&共同通讯作者)
[4] Shanguo Ji#, Hao Luo#, Zhenhua Yan*, Kai Yang* et al. Component Fluctuation Modulated Gelation Effect Enable Temperature Adaptability in Zinc-Ion Batteries. Advanced Energy Materials, 2024, 23, 2400063.(ESI高被引, 他引75次,IF=29.368,共同第一作者)
[5] Fan Li, Lina Ma*, Hao Luo* et al. Iron-Regulated D-Band Center in Fe-V2O5-n/rGO Heterostructures Enables Ultralong-Cycling Zinc-Iodine Batteries via Optimal Iodine Adsorption-Desorption Dynamics. Advanced Functional Materials, 2025: e12876. (IF=19,共同通讯作者)
[6] Zhe Gao, Hao Luo*, Mi Lu* et al. Multiscale Failure Mechanisms and Safety Assessment of Commercial Sodium-Ion Batteries. Advanced Functional Materials, 2025: e07323. (IF=19,共同通讯作者)
[7] Luo Hao, Wang Bo, Wang Dianlong* et al. Anodic Oxidation Strategy toward Structure-Optimized V2O3 Cathode via Electrolyte Regulation for Zn-Ion Storage. ACS Nano, 2020, 2020, 14(6): 7328-7337. (ESI热点&高被引, 他引305次 IF=15.881)
[8] Luo Hao, Wang Bo, Wang Dianlong* et al. Synergistic Deficiency and Heterojunction Engineering Boosted VO2 Redox Kinetics for Aqueous Zinc-Ion Batteries with Superior Comprehensive Performance. Energy Storage Materials, 2020, 33: 390-398. (ESI高被引, 他引249次,IF=20.8)
[9] Luo Hao, Wang Bo, Wang Dianlong* et al. Hierarchical design of hollow Co-Ni LDH nanocages strung by MnO2 nanowire with enhanced pseudocapacitive properties. Energy Storage Materials, 2019, 19: 370-378. (他引157次,IF=17.789)
[10] Yukun Li, Hao Luo*, Mi Lu* et al. An ultra-thick solvent-free electrode based on non-conservative pulsed shear field mixing. Energy Storage Materials, 2025, 77: 104218. (IF=20.2,共同通讯作者)
[11] Sheng Guo, Hao Luo*, Mi Lu* et al. Embedded Sensing: The Neural Frontier and Early-Warning Revolution in Battery Safety Monitoring. Energy Storage Materials, 2025: 104582. (IF=20.2,共同通讯作者)
[12] Li Xinliang*, Luo Hao*. Maximizing Terahertz Energy Absorption with MXene Absorber. Nano-Micro Letters, 2023, 15(1): 198. (IF=23.655,共同通讯作者)
[13] Luo Hao, Wang Dianlong*et al. Synergistic nanostructure and heterointerface design propelled ultra-efficient in-situ self-transformation of zinc-ion battery cathodes with favorable kinetics. Nano Energy, 2021, 81: 105601. (ESI高被引, 他引180次,IF=19.069)
[14] Hao Luo, Tiefeng Liu*, Mi Lu* et al. Diversified battery recycling: Advances in recovery techniques and value-added functional applications. Nano Energy, 2025: 110973. (IF=17.1,第一作者)
[15] Hao Luo*, Xiaolong Li* et al. Reconstructing the phase of vanadium oxides enables redox-catalysis manipulated reversible sulfur conversion for stable Zn–S batteries. Chemical Science, 2025, 16, 753(IF=7.4,第一作者&共同通讯作者)
[16] Lina Ma, Hao Luo*, Yudong Huang* et al. Phase reconfiguration of heterogeneous CoFeS/CoNiS nanoparticles for superior battery-type supercapacitors. Journal of Energy Chemistry, 2024, 96: 217-225. (IF=14.9,共同通讯作者)
[17] Shuzhe Yang, Hao Luo*, Mi Lu* et al. Residual fluoride self-activated effect enabling upgraded utilization of recycled graphite anode. Journal of Energy Chemistry, 2024, 93: 24-31. (IF=14.9,共同通讯作者)
[18] Shuzhe Yang, Hao Luo*, Mi Lu* et al. Lithium resurrection: Synergistic thermal-decomposition and electric-drive strategy enabling inactive lithium fully recycling. Journal of Energy Chemistry, 2025, 102: 842-851. (IF=14.9,共同通讯作者)
[19] Fuda Yu, Lanfang Que*, Hao Luo* et al. Temperature inversion enables superior stability for low-temperature Zn-ion batteries. Journal of Energy Chemistry, 2024, 91: 245-253. (IF=14.9,共同通讯作者)
[20] Hui Li, Hao Luo*, Mi Lu* et al. Synergistic intermolecular hydrogen-bonded cross-linking and steric hindrance effects enabling pomegranate-type LMFP@C for Li+ storage. Rare Metals, 2025, 44(1): 147-157. (IF=11,共同通讯作者)
[21] Yanping Guo, Hao Luo*, Zaijun Cheng et al. Synergistic defect engineering and gradient pore structure induce tellurium nanoclusters for high-performance aqueous zinc-tellurium batteries. Rare Metals, 2025: 1-12. (IF=11,共同通讯作者)
[22] Hui Li, Hao Luo*, Mi Lu* et al. Cavitation-enhanced disrupts the agglomeration of carbon nanotubes to construct dry electrodes with high-rate and high-loading. Journal of Colloid and Interface Science, 2025: 138662. (IF=9.7,共同通讯作者)
[23] Yun Luo, Hao Luo*, Mi Lu* et al. Ethanol-controlled release strategy induced local solvation polymerization of silicates for high-performance nano-silicon anode. Journal of Colloid and Interface Science, 2025, 689: 137224. (IF=9.7,共同通讯作者)
[24] Zejian Yi, Lanfang Que*, Hao Luo* et al.Mitigating crosstalk through water deactivation to achieve advanced Zn-ion batteries with superior temperature adaptability. Journal of Colloid and Interface Science, 2025, 693: 137591. (IF=9.7,共同通讯作者)
[25] Luo Hao, Dongliang Chao*et al. Atomic engineering promoted electrooxidation kinetics of manganese-based cathode for stable aqueous zinc-ion batteries. Nano Research, 2022, 15(9): 8603-8612. (IF=10.2,共同通讯作者)
[26] Hongwei Cai, Hao Luo*, Mi Lu* et al. Low-energy upcycling of spent graphite into high-F/C-ratio cathode for Li/CFx batteries. Separation and Purification Technology, 2025: 134004. (IF=9,共同通讯作者)
[27] Luo Hao, Wang Bo, Wang Dianlong* et al. Core-shell structured Fe3O4@NiS nanocomposite as high-performance anode material for alkaline nickel-iron rechargeable batteries. Electrochimica Acta, 2017, 231: 479-486. (IF=5.1)
[28] Luo Hao, Wang Bo, Wang Dianlong* et al. Highly conductive graphene-modified TiO2 hierarchical film electrode for flexible Li-ion battery anode. Electrochimica Acta, 2019, 313: 10-19. (IF=6.2)
通讯地址:
福建省厦门市集美区理工路600号厦门理工学院综合楼1301
邮 编:361024;座机电话:0592-6291328
