马龙涛
教授
电子邮箱:longtaoma@scut.edu.cn
工作经历
2023-至今 华南理工大学 材料科学与工程学院 教授
2022-2023 西北工业大学 教授
2020-2021 香港城市大学/大锌能源 博士后
教育经历
2017-2020 香港城市大学 博士
2014-2017 西北工业大学 硕士
2010-2014 中国地质大学(武汉)学士
获奖荣誉
1.2022“科睿唯安”全球高被引科学家;
2.陕西省高等学校科学技术一等奖(3/7),2021;
3.香港城市大学 周亦卿研究奖,2018,2019;
4.香港城市大学 杰出学术研究奖,2018,2019.
研究领域
主要从事柔性电化学储能器件、水系电池、新型高安全电池和金属-气体电池方面研究,包括高性能电极材料、高安全液态电解质、固态电解质、电解质与电极材料界面、电池结构设计。近年来,在Energy Environ. Scie., Adv. Mater., Angew. Chem. Int. Ed.,Adv. Energy Mater., Adv. Funct. Mater., ACS Nano, Nano Energy 等高水平期刊发表文章30余篇。其中,10篇论文被评为高被引论文,3篇论文被评为热点论文,论文总引用超过10000次,H-Index为55. 申请发明专利6项。担任eScience, Nano Research Energy期刊青年编委。
科研项目
1.国家自然科学基金 青年项目,基于固态溴和催化功能宿主的高能量、高安全柔性水系锌溴电池研究
2.西北工业大学 翱翔海外学者,柔性可穿戴电化学电源
发表文章
1.L. Ma, S. Chen, C Zhi*, et al. A High-Energy Aqueous Zn||NO2 Electrochemical Cell: A New Strategy for NO2 Fixation and Electric Power Generation, Energy & Environmental Science, 16(2023) 1125.
2.X. Yang, H. Fan, L. Ma*, et al. Aqueous Zinc Batteries with Ultra-Fast Redox Kinetics and High Iodine Utilization Enabled by Iron Single Atom Catalysts, Nano-Micro Letters, 15 (2023) 126.
3.X. Li, X. Wang, L. Ma*, W. Huang*, Solvation Structures in Aqueous Metal-Ion Batteries, Advanced Energy Materials, 12 (2022) 2202068.
4.L. Ma, Y. Ying, C. Zhi*, et al. Electrocatalytic Selenium Redox Reaction for High-Mass-Loading Zinc-Selenium Batteries with Improved Kinetics and Selenium Utilization, Advanced Energy Materials, 12 (2022), 2201322.
5.X. Wang, X. Li, H. Fan*, L. Ma*, Solid Electrolyte Interface in Zn-Based Battery Systems, Nano-Micro Letters, 14 (2022) 205.
6.L. Ma, Y. Ying, C Zhi*, et al. Towards Practical High-Areal Capacity Aqueous Zn Metal Batteries: Quantifying Hydrogen Evolution and a Solid-Ion Conductor for Stable Zn Anode, Advanced Materials, 33 (2021), 2007406. (Highly cited paper, Hot paper)
7.L. Ma, H. Cui, C Zhi*, et al. Accommodating Diverse Ions in Prussian Blue Analogs Frameworks for Rechargeable Batteries: The Electrochemical Redox Reactions, Nano Energy, 81(2021), 105632.
8.L. Ma, Y. Ying, C Zhi*, et al. Electrocatalytic Iodine Reduction Reaction Enabled Aqueous Zinc-Iodine Battery with both Superior Power and Energy Densities, Angewandte Chemie International Edition, 133 (2020), 3835.
9.L. Ma, S. Chen, C Zhi*, et al. Liquid-free all-solid-state Zinc batteries and encapsulation-free flexible batteries enabled by in-situ constructed polymer electrolyte, Angewandte Chemie International Edition, 132 (2020), 24044.
10.L. Ma, X. Li, C Zhi*, et al. Initiating a wearable solid-state Mg hybrid ion full battery with high voltage, high capacity and ultra-long lifespan in air, Energy Storage Materials, 31 (2020), 451.
11.L. Ma, S. Chen, C Zhi*, et al. Hydrogen-Free and Dendrite-Free All-Solid-State Zn-Ion Batteries, Advanced Materials, 32(2020), 1908121. (Highly cited paper)
12.L. Ma, S. Chen, C Zhi*, et al. Achieving high-voltage and high-capacity aqueous rechargeable zinc ion battery by incorporating two-species redox reaction, Advanced Energy Materials, 2019, 1902446. (Highly cited paper)
13.L. Ma, N. Li, C Zhi*, et al. Achieving both high voltage and high capacity in aqueous zinc ion battery for record-high energy density, Advanced Functional Materials, 2019, 1906142. (Highly cited paper)
14.L. Ma, S. Chen, C Zhi*, et al. Initiating A Mild Aqueous Electrolyte Co3O4/Zn Battery with 2.2 V-High Voltage and 5000-Cycle Lifespan by a Co (III) Rich-electrode, Energy & Environmental Science, 11(2018), 2521. (Highly cited paper)
15.L. Ma, S. Chen, C Zhi*, et al. Super‐Stretchable Zinc-Air Batteries Based on an Alkaline‐Tolerant Dual‐Network Hydrogel Electrolyte, Advanced Energy Materials, 2019, 12, 1803046. (Highly cited paper)
16.L. Ma, Y. Zhao, C Zhi*, et al. A Usage Scenario Independent “Air Chargeable” Flexible Zinc Ion Energy Storage Device, Advanced Energy Materials, 2019, 19, 1900509.
17.L. Ma, S. Chen, C Zhi*, et al. Flexible Waterproof Rechargeable Hybrid Zinc Batteries Initiated by Multifunctional Oxygen Vacancies-Rich Cobalt Oxide, ACS Nano, 12 (2018) 8597. (Highly cited paper)
18.L. Ma, S. Chen, C Zhi*, et al. Single-Site Active Iron-Based Bifunctional Oxygen Catalyst for a Compressible and Rechargeable Zinc-Air Battery, ACS Nano, 12 (2018) 1949. (Highly cited paper)