牛树章 副教授
个人介绍:
牛树章,工学博士,副教授,深圳市高层次专业人才。2016年7月毕业于清华大学材料科学与工程专业,获工学博士学位。2016年9月至2018年10月,在清华-伯克利深圳学院从事博士后研究工作。2018年11月至2022年2月,在南方科技大学前沿与交叉科学研究院,担任研究助理教授(副研究员),硕士生导师。2022年3月加入深圳技术大学新材料与新能源学院。主要研究领域包括纳米碳材料的结构设计、功能化调控与制备及电化学储能应用研究。在Advanced Energy Materials, Energy Storage Materials等国际权威刊物发表SCI论文30余篇,他引2700余次。申请/授权国家发明专利16项。先后主持国家自然科学基金面上项目、青年基金、广东省面上项目,深圳市面上基金、博士后基金面上项目和企业横向等多项科研项目。教授课程包含《锂离子电池材料与技术》、《车载动力电池与储能技术》、《储能原理与技术》及《柔性电子学》等课程。
工作经历:
2025.03- 深圳技术大学,新材料与新能源学院,副教授(长聘)
2022.03-2025.02 深圳技术大学,新材料与新能源学院,助理教授2018.11-2022.02 南方科技大学,研究助理教授(副研究员)
2016.09-2018.10 清华-伯克利深圳学院,博士后
2009.07-2011.05 沧州明珠股份有限公司,工程师
主要荣誉:
• 2019年入选深圳市高层次专业人才(后备级)
• 2015年,清华大学深圳研究生院“景芝科研一等奖”
• 2024年,Energy Materials and Devices青年编委
• 2024年,深圳技术大学“优秀共产党员”
• 2024年,深圳技术大学“优秀班主任”
研究方向:
1.石墨烯及碳纳米材料
2.能源存储与转换材料
3.锂电池材料,如锂金属负极、硅碳负极及快充电池材料。
科研项目:
1.国家自然科学基金面上项目,2020.01-2023.12,主持;
2.广东省基础与应用基础研究基金面上项目,2019.10–2022.09,主持;
3.深圳市基础研究面上项目,2020.03-2023.02,主持;
4.国家自然科学青年基金,2018.1-2018.12,主持;
5.中国博士后基金面上项目,2017.8-2018.10,主持;
6.深圳市科技创新委员会重点项目,2019.4-2020.3,参与;
7.国家自然科学基金青年基金项目,2014.1-2016.12,参与;
8.校企合作项目,2022.07-2025.06,主持。
代表论文:
2025年
[37]Zhang, Q. C.; Wang, X.; Mao, Z. Y.; Yang, A. B.;Niu, S. Z.*; Gao, W.; Wang, M. Ferroelectric lead zirconate titanate-modified separator enabling stable anode-free lithium metal batteries via dual regulation of Li plus flux and anion-enriched solid electrolyte interphase. J. Colloid Interface Sci. 2025, 703.
[36]Xun, J. H.; Chen, Z. R.; Meng, A. Y.; Huang, L.;Niu, S. Z.; Zeng, S. Z.; Yu, X.; Liu, W. F.; Fu, D. J.; Liu, X. G. The application of N-doped distillers' grains porous carbon in the oxygen reduction reaction. Diamond Relat. Mater. 2025, 155.
[35]Wang, X.; Xu, L.;Niu, S. Z.*; Zhang, Q. C.; Lian, Q.; Xiang, S. L.; Mao, Z. Y.; Han, Y.; Huang, Y. L.; Li, G. T.et al. Long-Cycling, Fast-Charging Lithium Metal Batteries Enabled by Nickel-Carbon Composite Nanosheet Arrays Modified Lithium Metal Anodes. Small 2025, 21 (4).
[34]Shi, H. F.*; Han, S.; Hou, Z. H.; Lan, H. B.; Niu, S. Z.*; Li, Q*. Interactive issues and strategic solutions for aqueous Zn metal anodes. J Energy Chem 2025, 103, 163.
2024年
[33]Sun, W. Y.; Cao, J. K.; Han, S.; Shi, H. F.; Lu, G. X.; Zhu, X. Y.; Xu, L.; Ghazi, Z. A.; Fan, D. H.; Han, D. L.Niu, S. Z.*et al. Synergy of structural engineering and VO2 self-transformation enables ultra-high areal capacity cathodes for zinc-ion batteries.Carbon 2024, 226.
[32]Shi, H. F.*; Cao, J. K.; Sun, W. Y.; Lu, G. X.; Lan, H. B.; Xu, L.; Ghazi, Z. A.; Fan, D. H.; Mao, Z. Y.; Han, D. L.Niu, S. Z.*et al.Ultrasmall, Amorphous V2O3Intimately Anchored on a Carbon Nanofiber Aerogel Toward High-Rate Zinc-Ion Batteries. ACS Appl. Mater. Interfaces 2024, 16 (15), 18812.
[31]Qiu, J. W.; Qiu, R. L.; Mao, Z. Y.; Han, Y.; Madhusudan, P.; Wang, X.; Wang, C.; Qi, C. S.; Yu, X.; Zeng, S. Z.Niu, S. Z.*. A review on copper current collector used for lithium metal batteries: Challenges and strategies. J Energy Storage 2024, 100.
2023年
[30]Zhang, Q. C.; Xu, L.; Yue, X. Y.*; Liu, J. J.; Wang, X.; He, X. Y.; Shi, Z. D.;Niu, S. Z.*; Gao, W.; Cheng, C*.et al. Catalytic Current Collector Design to Accelerate LiNO3 Decomposition for High-Performing Lithium Metal Batteries. Adv. Energy Mater. 2023, 13 (43).
[29]Zeng, S. Z.; Wang, S. X.; Kong, L. B.; Tian, Y. C.; He, B.; Yu, X.;Niu, S. Z.; Fu, D. J.; Han, P. G. Low-Cost Organodisulfide Polymer for Ultrafast High-Capacity Cathode Materials. Acs Applied Energy Materials 2023, 6 (16), 8479.
[28]Xu, L.; Zhang, Q. C.;Niu, S. Z.*; Wang, X.; Lian, Q.; Huang, Y. L.; Shi, R.; Amini, A.; Cheng, C. Organic Eutectic Mixture Incorporated with Graphene Oxide Sheets as Lithiophilic Artificial Protective Layer for Dendrite-Free Lithium Metal Batteries. Adv. Energy Mater. 2023, 13 (12).
[27]Shi, H. F.*; Cao, J. K.; Han, S.; Sun, W. Y.; Zhu, X. Y.; Lu, G. X.; Lan, H. B.; Yang, H. C.;Niu, S. Z.*. Hierarchical carbon hollow nanospheres coupled with ultra-small molybdenum carbide as sulfiphilic sulfur hosts for lithium-sulfur batteries. Rsc Adv 2023, 13 (30), 20810.
2022年
[26]Niu, S. Z.; Zhang, S. W.; Li, D. Y.; Wang, X.; Chen, X. M.; Shi, R.; Shen, N.; Jin, M. T.; Zhang, X.; Lian, Q.et al. Sandwiched Li plating between Lithiophilic-Lithiophobic gradient Silver@Fullerene interphase layer for ultrastable lithium metal anodes. Chem. Eng. J. 2022, 429.
[25]Jin, M. T.; Zhang, X.;Niu, S. Z.; Wang, Q.; Huang, R. Q.; Ling, R. H.; Huang, J. Q.; Shi, R.; Amini, A.; Cheng, C. Strategies for Designing High-Performance Hydrogen Evolution Reaction Electrocatalysts at Large Current Densities above 1000 mA cm-2. ACS Nano 2022, 16 (8), 11577.
2022年以前
[24]Zhang, X.; Jin, M. T.; Lian, Q.; Peng, O. W.;Niu, S. Z.; Ai, Z.; Amini, A.; Song, S. X.; Cheng, C. Ion modification of transition cobalt oxide by soaking strategy for enhanced water splitting. Chem. Eng. J. 2021, 423.
[23]Wang, X.; Huang, R. Q.;Niu, S. Z.*; Xu, L.; Zhang, Q. C.; Amini, A.; Cheng, C*. Research progress on graphene-based materials for high-performance lithium-metal batteries. New Carbon Mater 2021, 36 (4), 711.
[22]Shen, N.; Chen, S.; Shi, R.;Niu, S. Z.; Amini, A.; Cheng, C. Phase Transition Hysteresis of Tungsten Doped VO2 Synergistically Boosts the Function of Smart Windows in Ambient Conditions. Acs Applied Electronic Materials 2021, 3 (8), 3648.
[21]Shen, N.; Chen, S.; Huang, R. Q.; Huang, J. Q.; Li, J. Y.; Shi, R.;Niu, S. Z.; Amini, A.; Cheng, C. Vanadium dioxide for thermochromic smart windows in ambient conditions. Materials Today Energy 2021, 21.
[20]Jin, M. T.; Zhang, X.; Shi, R.; Lian, Q.;Niu, S. Z.; Peng, O. W.; Wang, Q.; Cheng, C. Hierarchical CoP@Ni2P catalysts for pH-universal hydrogen evolution at high current density. Applied Catalysis B-Environment and Energy 2021, 296.
[19]Niu, S. Z.; Zhang, S. W.; Shi, R.; Wang, J. W.; Wang, W. J.; Chen, X. M.; Zhang, Z. Q.; Miao, J.; Amini, A.; Zhao, Y. S.et al. Freestanding agaric-like molybdenum carbide/graphene/N-doped carbon foam as effective polysulfide anchor and catalyst for high performance lithium sulfur batteries. Energy Storage Mater. 2020, 33, 73.
[18]Li, X.#;Niu, S. Z.#; Nan, D.; Li, B. H.; He, Y. B.; Kang, F. Y. sp-sp2 hybrid-conjugated microporous polymer-derived Pd-encapsulated porous carbon materials for lithium-sulfur batteries. Chem. Commun. 2019, 55 (68), 10084.
[17]Hao, B. Y.; Li, H.; Lv, W.; Zhang, Y. B.;Niu, S. Z.; Qi, Q.; Xiao, S. J.; Li, J.; Kang, F. Y.; Yang, Q. H. Reviving catalytic activity of nitrides by the doping of the inert surface layer to promote polysulfide conversion in lithium-sulfur batteries. Nano Energy 2019, 60, 305.
[16]Chen, Y. W.;Niu, S. Z.; Lv, W.; Zhang, C.; Yang, Q. H. Promoted conversion of polysulfides by MoO2 inlaid ordered mesoporous carbons towards high performance lithium-sulfur batteries. Chin. Chem. Lett. 2019, 30 (2), 521.
[15]Zhang, J.; Wang, D. W.; Lv, W.; Qin, L.;Niu, S. Z.; Zhang, S. W.; Cao, T. F.; Kang, F. Y.; Yang, Q. H. Ethers Illume Sodium-Based Battery Chemistry: Uniqueness, Surprise, and Challenges. Adv. Energy Mater. 2018, 8 (26).
[14]Shi, H. F.#;Niu, S. Z.#; Lv, W.; Zhou, G. M.; Zhang, C.; Sun, Z. H.; Li, F.; Kang, F. Y.; Yang, Q. H. Easy fabrication of flexible and multilayer nanocarbon-based cathodes with a high unreal sulfur loading by electrostatic spraying for lithium-sulfur batteries. Carbon 2018, 138, 18.
[13]Qin, L.; Yuan, Y. F.; Wei, W.; Lv, W.;Niu, S. Z.; He, Y. B.; Zhai, D. Y.; Kang, F. Y.; Kim, J. K.; Yang, Q. H.et al. Graphene-Directed Formation of a Nitrogen-Doped Porous Carbon Sheet with High Catalytic Performance for the Oxygen Reduction Reaction. Journal of Physical Chemistry C 2018, 122 (25), 13508.
[12]Pan, Z. Z.; Lv, W.; He, Y. B.; Zhao, Y.; Zhou, G. M.; Dong, L. B.;Niu, S. Z.; Zhang, C.; Lyu, R. Y.; Wang, C.et al. A Nacre-Like Carbon Nanotube Sheet for High Performance Li-Polysulfide Batteries with High Sulfur Loading. Adv. Sci. 2018, 5 (6).
[11]Zheng, C.;Niu, S. Z.; Lv, W.; Zhou, G. M.; Li, J.; Fan, S. X.; Deng, Y. Q.; Pan, Z. Z.; Li, B. H.; Kang, F. Y.et al. Propelling polysulfides transformation for high-rate and long-life lithium-sulfur batteries. Nano Energy 2017, 33, 306.
[10]Niu, S. Z.; Wu, S. D.; Lu, W.; Yang, Q. H.; Kang, F. Y. A one-step hard-templating method for the preparation of a hierarchical microporous-mesoporous carbon for lithium-sulfur batteries. New Carbon Mater 2017, 32 (4), 289.
[9]Luo, C.; Lv, W.; Deng, Y. Q.; Zhou, G. M.; Pan, Z. Z.;Niu, S. Z.; Li, B. H.; Kang, F. Y.; Yang, Q. H. A Dual-Function Na2SO4 Template Directed Formation of Cathode Materials with a High Content of Sulfur Nanodots for Lithium-Sulfur Batteries. Small 2017, 13 (27).
[8]Shi, Y. T.; Lv, W.;Niu, S. Z.; He, Y. B.; Zhou, G. M.; Chen, G. H.; Li, B. H.; Yang, Q. H.; Kang, F. Y. A Carbon-Sulfur Hybrid with Pomegranate-like Structure for Lithium-Sulfur Batteries. Chem-Asian J 2016, 11 (9), 1343.
[7]Niu, S. Z.; Zhou, G. M.; Lv, W.; Shi, H. F.; Luo, C.; He, Y. B.; Li, B. H.; Yang, Q. H.; Kang, F. Y. Sulfur confined in nitrogen-doped microporous carbon used in a carbonate-based electrolyte for long-life, safe lithium-sulfur batteries. Carbon 2016, 109, 1.
[6]Niu, S. Z.; Lv, W.; Zhou, G. M.; Shi, H. F.; Qin, X. Y.; Zheng, C.; Zhou, T. H.; Luo, C.; Deng, Y. Q.; Li, B. H.et al. Electrostatic-spraying an ultrathin, multifunctional and compact coating onto a cathode for a long-life and high-rate lithium-sulfur battery. Nano Energy 2016, 30, 138.
[5]Luo, C.; Niu, S. Z.; Zhou, G. M.; Lv, W.; Li, B. H.; Kang, F. Y.; Yang, Q. H. Dual-functional hard template directed one-step formation of a hierarchical porous carbon-carbon nanotube hybrid for lithium-sulfur batteries. Chem. Commun. 2016, 52 (82), 12143.
[4]Niu, S. Z.; Lv, W.; Zhou, G. M.; He, Y. B.; Li, B. H.; Yang, Q. H.; Kang, F. Y. N and S co-doped porous carbon spheres prepared using L-cysteine as a dual functional agent for high-performance lithium-sulfur batteries. Chem. Commun. 2015, 51 (100), 17720.
[3]Niu, S. Z.; Lv, W.; Zhang, C.; Shi, Y. T.; Zhao, J. F.; Li, B. H.; Yang, Q. H.; Kang, F. Y. One-pot self-assembly of graphene/carbon nanotube/sulfur hybrid with three dimensionally interconnected structure for lithium-sulfur batteries. J. Power Sources 2015, 295, 182.
[2]Niu, S. Z.; Lv, W.; Zhang, C.; Li, F. F.; Tang, L. K.; He, Y. B.; Li, B. H.; Yang, Q. H.; Kang, F. Y. A carbon sandwich electrode with graphene filling coated by N-doped porous carbon layers for lithium-sulfur batteries. J. Mater. Chem. A 2015, 3 (40), 20218.
[1]Li, F. F.; Lu, W.;Niu, S. Z.; Li, B. H. Preparation and electrochemical performance of a graphene-wrapped carbon/sulphur composite cathode. New Carbon Mater 2014, 29 (4), 309.
代表专利:
1. 符冬菊;周伟;曾绍忠;韩培刚;胡照;牛树章;候少宇,废旧磷酸铁锂电池正极材料的再生方法,申请号:CN202310182897.3.授权公告号:CN116119636B.
2. 程春,王信,牛树章,张启程,三维复合集流体及其制备方法和应用,一种复合锂金属负极集流体及其制备方法和应用,申请号:CN202210468341.6.授权公告号:CN114792805B.
3. 程春,牛树章,陈晓梅,王信,黄润青,一种复合锂金属负极集流体及其制备方法和应用,申请号:202011615425.5.公开(公告)号:CN 112768697 A.
4. 程春,牛树章,石润,黄润青,一种石墨化碳泡沫支撑碳材料/碳化钼复合材料及其制备方法和用途,申请号:CN201911105531.6.公开(公告)号:CN110803685A. (授权).
5. 吕伟,牛树章,张思伟,游从辉,杨全红,康飞宇,锂硫电池正极材料、其制备方法、正极片及锂硫电池,申请号:CN 201910013345.3.公开(公告)号:CN 109742359 A. (授权).
6. 吕伟,牛树章,游从辉,杨全红,康飞宇;一种锂离子电池用石墨烯硅负极材料及制备方法,申请号:CN201811475188.X.公开(公告)号:CN109473658A. (授权).
7. 吕伟,石会发,牛树章,游从辉,杨全红,康飞宇,一种锂硫电池硫电极的制备方法及应用,申请号:CN201810468684.6.公开(公告)号:CN108666533A. (授权).
8. 吕伟,陈亚炜,牛树章,游从辉,杨全红,康飞宇,一种锂硫电池正极材料及制备方法、锂硫电池.申请号:CN201810340218.X.公开(公告)号:CN108550813A. (授权).
9. 吕伟,潘正泽,杨全红,赵严,牛树章,石会发,游从辉,康飞宇,一种锂硫电池用正极材料及其使用方法,申请号:CN201710097528.9.公开(公告)号:CN106711427A. (授权).
10. 杨全红,郑程,牛树章,游从辉,吕伟,李宝华,康飞宇,基于石墨烯/氧化物的电极材料及包含该电极材料的锂硫电池,申请号:CN201610910362.3.公开(公告)号:CN106450197A. (授权)
专著章节:
1. 撰写专著《石墨烯电化学储能技术》第四章,题目为:石墨烯在锂硫电池中的应用,杨全红,孔德斌,吕伟等编著,华东理工大学出版社。“十三五”国家重点出版物出版规划项目。
2. 撰写专著《储能用碳基纳米材料》第九章中锂硫电池部分,题目为:其他新型储能电池,康飞宇、干林、吕伟等编著。科学出版社,2020.3。
★ 课题组招收访问学生,每年招收1-2位硕士研究生,欢迎大家积极联系!
联系方式:
电子邮箱:niushuzhang@sztu.edu.cn
