马龙涛


的个人主页 http://teacher.nwpu.edu.cn/longtaoma

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基本信息 The basic information

马龙涛

柔性电子研究院

博士研究生毕业

哲学博士

教授

材料科学与工程-材料物理与化学,化学-物理化学(含:化学物理)

iamltma@nwpu.edu.cn

工作经历 Work Experience

2022- 西北工业大学,柔性电子研究院  教授

2016.11-2017.5 香港理工大学,应用物理系,研究助理/访问学生 (导师:黄海涛 教授)

教育经历 Education Experience

2017. 6 - 2020. 7   香港城市大学,材料科学与工程系   博士 (导师:支春义 教授);

2014. 9 - 2017. 3   西北工业大学,材料学院   硕士 (导师:樊慧庆 教授);

2010. 9 - 2014. 6   中国地质大学(武汉),材料与化学学院  本科;

综合介绍 General Introduction

        马龙涛 教授,翱翔海外学者,主要从事柔性可穿戴储能器件方面研究,包括高性能电极材料、高安全电解质、固态电解质的制备以及电解质与电极材料界面、电池结构的设计。迄今为止,以第一/通讯作者在Energy& Environmental Science, Advanced Materials, Angewandte Chemie International EditionAdvanced Energy Materials, Advanced Functional Materials , ACS Nano, Nano Energy等期刊发表论文 30 余篇。其中,11 篇论文入选高被引论文3 篇论文入选热点论文,论文总引用 7300 余次H-Index 为 49 (Google Scholar). 申请发明专利 项。

科学研究 Scientific Research

研究兴趣

1. 柔性可穿戴电池;        2. 水系电池;         3. 金属空气电池;           4. 聚合物固态电解质。

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学术成果 Academic Achievements

Selected Publications

After joining NWPU

2. X. Li, X. Wang, L. Ma*, W. Huang*, Solvation Structures in Aqueous Metal-Ion BatteriesAdvanced Energy Materials, Accept. 

1. L. Ma, Y. Ying, C. Zhi*, et al. Electrocatalytic Selenium Redox Reaction for High-Mass-Loading Zinc-Selenium Batteries with Improved Kinetics and Selenium UtilizationAdvanced Energy Materials, 12 (2022), 2201322. 


Before joining NWPU

1. 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)

2. L. Ma, H. Cui, C. Zhi*, et al. Accommodating Diverse Ions in Prussian Blue Analogs Frmeworks for Rechargeable Batteries: The Electrochemical Redox Reactions, Nano Energy, 81(2021), 105632.

3.  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.

4. 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.

5. 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.

6. 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)

7. 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, 9 (2019), 1902446.

8. 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), 2521-2530. (Highly cited paper)

9. 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, 29 (2019), 1906142. (Highly cited paper, Hot paper)

10. L. Ma, S. Chen, C. Zhi*, et al. SuperStretchable Zinc-Air Batteries Based on an AlkalineTolerant DualNetwork Hydrogel Electrolyte, Advanced Energy Materials, 12 (2019), 1803046. (Highly cited paper)

11. L. Ma, Y. Zhao, C. Zhi*, et al. A Usage Scenario Independent “Air Chargeable” Flexible Zinc Ion Energy Storage Device, Advanced Energy Materials, 19 (2019), 1900509.

12. 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) 1949-1958. (Highly cited paper)

13. 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) 8597-8606. (Highly cited paper)

14. S. Chen#, L. Ma#, et al. Uniform Virus-like Co-N-Cs electrocatalyst derived from Prussian Blue Analog for Stretchable Zinc-Air Batteries. Advanced Functional Materials, 2020, 1908945. (#: equal contribution)

15. Y. Zhao#, L. Ma#, C. Zhi*, et al. Inhibiting Grain Pulverization and Sulfur Dissolution of Bismuth Sulfide by Ionic Liquid Enhanced Poly(3,4-ethylenedioxythiophene):Poly(styrenesulfonate) for High-Performance Zinc-Ion Batteries, ACS Nano, 13 (2019), 7270-7280. (#: equal contribution)

16. H. Li#, L. Ma#, C. Zhi*, et al. Advanced Rechargeable Zinc-Based Batteries: Recent Progress and Future Perspectives, Nano Energy, 62 (2019), 550-587. (#: equal contribution)

17. S. Chen#, L. Ma#, A Flexible Solid-State Zinc Ion Hybrid Supercapacitors Based on co-Polymer Derived Hollow Carbon Spheres, Journal of Materials Chemistry A, 7 (2019) , 7784-7790. (#: equal contribution)

18. X. Li#, L. Ma#, C. Zhi*, et al. Hydrated hybrid vanadium oxide nanowires as the superior cathode for aqueous Zn battery, Materials Today Energy, 2019, DOI: 10.1016/j.mtener,2019.100361. (#: equal contribution)

19. L. Ma, H. Fan*, H Huang*, et al. Towards High Areal Capacitance, Rate Capability and Tailorable Supercapacitor: Co3O4@ Polypyrrole Core-Shell Nanorod Bundle Arrays Electrode, Journal of Materials Chemistry A, 6 (2018), 19058-19065.

20. L. Ma, H. Fan*, J. Wang, et al. Water-Assisted Ions in situ Intercalation for Porous Polymericgraphitic Carbon Nitride Nanosheets with Superior Photocatalytic Hydrogen Evolution Performance. Applied Catalysis B: Environmental 190 (2016) 93-102. (Highly cited paper)

21. L. Ma, H. Fan*, M. Li, et al. A simple Melamine-Assisted Exfoliation of Polymeric Graphitic Carbon Nitrides For Highly Efficient Hydrogen Production from Water under Visible Light, Journal of Materials Chemistry A, 3 (2015): 22404-22412.

22. L. Ma, H. Fan*, Y. Zhao, et al. Protonation of Graphitic Carbon Nitride (g-C3N4) for an Electrostatically Self-Assembling Carbon@g-C3N4 Core–Shell Nanostructure toward High Hydrogen Evolution. ACS Sustainable Chemistry& Engineering. 5 (2017), 7093–7103. (Highly cited paper)


Patents

1. C. Zhi, L. Ma, Liquid-free all-solid-state Zn batteries and encapsulation-free flexible batteries enabled by in-situ constructed polymer electrolyte, 28 Aug 2020, Priority No. 63/071,519.

2. C. Zhi, L. Ma, Z. Tang, 用於能量存儲裝置的電解質和使用該電解質的能量存儲裝置, 25 May 2020, Priority No. 202010447537.8.

3. C. Zhi, F. Mo, L. Ma, Z. Tang, An Electrical Energy Storage Device, an Electrolyte for Use in an Electrical Energy Storage Device, and a Method of Preparing the Device. 8 Jul. 2019, Priority No. 16/504, 568

4. C., Y. Zhao, Z. Tang, L.Ma. An Energy Storage Device and an Electrode for an Energy Storage Device, 28 Jun 2019, Priority No. 16/456,114.

5. C., X. Li, L. Ma, Q. Yang. An Energy Storage Device and a Method of Preparing The Device, 23 May 2019, Priority No. 16/420,251.

6. C. Zhi, L. Ma, Z. Tang, H. Li. An Electrical Energy Storage Apparatus and a Method of Preparing the Same, 8 Apr. 2019, Priority No. 16/377,608.

7. C. Zhi, L. Ma, Z. Tang, H. Li. An Energy Storage Device, an Electrolyte for Use in an Energy Storage Device and a Method of Preparing the Electrolyte, 11 Dec. 2018, Priority No. 16/216,168.

8. C. Zhi, L. Ma, An Energy Storage Device, an Electrode and a Method of Forming an Energy Storage Device, 16 Jul. 2018, Priority No. 16/035,967.


团队信息 Team Information

招生方向:

材料化学、有机化学、无机化学、材料学、能源化学


课题组成员:


李晓敏    王鑫钰


荣誉获奖 Awards Information

1. 2020年,陕西省高等学校科学技术一等奖(3/7

2. 2019&2020年,香港城市大学周亦卿研究生院奖;

3. 2019&2020年,香港城市大学杰出学术奖;

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