个人简介
巩峰 能源工程系副研究员,至善学者A类,硕导(动力工程及工程热物理)
个人简介 教学课程 科研、教改项目 论文&专著 专利申请 荣誉、奖励 指导学生
1988年8月生,江苏宿迁人。2011年本科毕业于四川大学,2015年博士毕业于新加坡国立大学,回国工作前在在美国俄克拉荷马大学从事博士后研究工作。2019年3月入选东南大学“至善学者A类”人才计划回到东南大学能源与环境学院工作,担任能源热转换及其过程测控教育部重点实验室副主任。在热能转换、传输与存储设计的基础理论、材料和系统等领域开展了大量的研究,近四年来,在Nano Energy, Applied Energy,Advanced Materials,Advanced Functional Materials,Journal of American Chemistry Society,Advanced Science等知名期刊发表文章近50篇,其中第一作者和通讯作者文章近35篇,总引用近1200次,H-index 20, i10-index 28。所发表的第一与通讯作者论文中有9篇高被引论文和2篇热点论文。申请发明专利16项;主持国家自然基金一项、国家重点研发项目子课题一项,省部级项目两项;作为第二主持人参与国家级项目6项。
Dr. Gong was born in Suqian city, Jiangsu Province, China in August of 1988. After finished his bachelor in Sichuan University in 2011, he went to National University of Singapore for his PhD study. Before coming back to China, he did postdoc research fellow in the University of Oklahoma for one year. In recent years, he did a lot of research on thermal energy conversion, transfer and storage, including materials, devices and systems. In the past 4 year, he has published more than 30 peer-reviewed papers as the first author or corresponding author.The total citation is around 1200 and my H-index is 19. Among those papers,there are 9 highly-cited papers and 2 hot papers. The journals include Nano Energy,Advanced Materials,Advanced Functional Materials,Journal of American Chemistry Society,Advanced Science,Carbon and so on. He also applied 16 patents. He hosted one NSFC funding and 2 funding from the ministry.
教学课程
《能源材料计算与设计》
《Computational Materials Science》
《专业人才论坛》
《新能源技术基础》全英文
科研 教改项目
国家自然基金青年基金:石墨烯气凝胶导热性能的多尺度理论与实验研究 主持
科技部重点研发计划项目子课题(2020-2022)主持
2019年南京市留学人员科技创新项目择优资助 主持
东南大学学科振兴计划课题 主持
东南大学至善学者A类计划项目 主持
东南大学引进人才启动项目 主持
省科技厅国际合作项目 主持
代表性论文(IF:影响因子,*通信作者,#共同一作)
https://www.researchgate.net/profile/Feng_Gong2
https://scholar.google.com/citations?hl=en&user=h5msyd4AAAAJ&view_op=list_works&sortby=pubdate
专利申请
申请发明专利10余项
荣誉 奖励
第十三届全国大学生节能减排社会实践与科技竞赛全国特等奖(指导教师:肖睿,巩峰)
第十三届全国大学生节能减排社会实践与科技竞赛全国三等奖(指导教师:巩峰)
第一届能源与环境会议最佳报告奖
第十届中泰可再生能源会议邀请报告
获得院级青年教师教学竞赛一等奖一次,三等奖两次。
江苏省可再生能源学会会员
微能源回收利用领域的研究工作被东南大学主页报道:
https://www.seu.edu.cn/2020/0515/c17409a328055/page.htm
废弃物新型利用被中国科学报报道:
http://news.sciencenet.cn/htmlnews/2020/5/440567.shtm
担任Nano Energy,Chemical Engineering Journal, International Journal of Heat and Mass Transfer等期刊审稿人。
指导学生
研究生:吕玉林,王思珺
本科生:夏大维,裴旭东,曾伟,王文彬,周强,李昊
研究领域
1.先进能源转换材料
2.多尺度传热理论计算
3.微能源回收利用
4.环境治理和净化
5.可再生能源合成燃料
近期论文
查看导师新发文章
(温馨提示:请注意重名现象,建议点开原文通过作者单位确认)
1. Lv Y. Gong F.*, Rui Xiao* et al., A flexible electrokinetic power generator derived from paper and ink for wearable electronics, Applied Energy, in press. (IF: 8.4)
2. Gong F., Rui Xiao* et al., Agricultural waste-derived Moisture-absorber for All-weather Atmospheric Water Collection and Electricity Generation, Nano Energy (2020) 104922. (IF: 16.6)
3. Li Y#, Gong F.#, et al., Crystalline isotype heptazine-/triazine-based carbon nitride heterojunctions for an improved hydrogen evolution, Applied Catalysis B: Environmental (2020) 268, 118381 (IF: 15.3).
4. Gong F.,* Wang W. et al., Solid waste and graphite derived solar steam generator for highly-efficient and cost-effective water purification, Applied Energy (2020), 261, 114410. (IF: 8.4)
5. Gong F., et al., Facile and Controllable Synthesis of Co2V2O7 Microplatelets Anchored on Graphene Layers toward Superior Li-Ion Battery Anodes, Energy & Fuel (2020) 34, 7616-7621. (IF: 3.4).
6. Xia D., Gong F., et al., Pure-phase β-Mn2V2O7 interconnected nanospheres as high-performance lithium ion battery anode, Chemical Communications (2020) (IF: 6.2).
7. Gong F. et al. Scalable, eco-friendly and ultrafast solar steam generators based on one-step derived carbon sponges toward water purification, Nano Energy, 58 (2019) 322–330. (IF: 16.6).
8. Kong W.#, Gong F.# et al. MnO2-Ti3C2Tx MXene nanohybrid: an efficient and durable electrocatalyst toward artificial N2 fixation to NH3 under ambient conditions, Journal of Materials Chemistry A, (2019), 7, 18823-18827 (IF: 11.3)
9. Huang H.#, Gong F.# et al, Mn3O4 nanoparticles@reduced graphene oxide composite: An efficient electrocatalyst for artificial N2fixation to NH3 at ambient conditions, Nano Research, (2019), 12, 1093-1098. (IF: 8.5).
10. Wang S.#, Gong F.# et al., Graphene-template controlled cuboid-shaped high capacity VS4 nanoparticles as anode for sodium ion batteries, Advanced Functional Materials (2018),1801806 (IF: 15.6).
11. Gong F. et al. Enhanced Electrochemical and Thermal Transport Properties of Graphene/MoS2 Heterostructures for Energy Storage: Insights from Multiscale Modeling, ACS Applied Materials and Interface(2018), 10, 14314-14621, (IF: 8.5).
12. Gong F. et al. Systematic comparison of hollow and solid Co3V2O8 micro-pencils as advanced anode materials for lithium ion batteries, Electrochimica Acta 264 (2018) 358-366.(IF: 5.1).
13. Xia D., Gong F.* et al. Molybdenum and tungsten disulfides-based nanocomposite films for energy storage and conversion, Chemical Engineering Journal 348 (2018) 908-928. (IF: 8.4).
14. Wang Z.#Gong F.# et al.,Electrocatalytic Hydrogenation of N2 to NH3 by MnO: Experimental and Theoretical Investigations, Advanced Science (2018), 1801182. (IF: 15.6).
15. Wang Z.#, Gong F.# et al. Synergetic enhancement of thermal conductivity by constructing hybrid conductive network in the segregated polymer composites, Composites Science and Technology (2018), 162, 7-13. (IF: 6.7).
16. Gong F. et al. Recent advances in graphene-based free-standing films for thermal management: synthesis, properties and applications, Coatings (2018) 8, 63. (IF: 2.4).
17. Gong F. et al. Predictions of the thermal conductivity of multiphase nanocomposites with complex structures, Journal of Materials Science (2018),53, 12157–12166. (IF: 3.4).
18. Gong F.* et al. Novel spherical cobalt/nickel mixed-vanadates as high-capacity anodes in lithium ion batteries, Journal of Alloys and Compounds (2018), 766, 442-449. (IF: 4.2).
19. Peng S., Gong F., et al. Necklace-Like Multi-Shelled Hollow Spinel Oxides with Oxygen Va-cancies for Efficient Water Electrolysis, J. Am. Chem. Soc. 2018, 140, 42, 13644-13653. (IF: 14.4).
20. Gong F. et al. A Facile Approach to Tune the Electrical and Thermal Properties of Graphene Aerogels by Including Bulk MoS2, Nanomaterials, (2017), 7, 420. (IF: 3.5).
21. Gong F. et al. Effective thermal transport properties in multiphase biological systems containing carbon nanomaterials, RSC Advances, (2017), 7, 13615. (IF: 3.1).
22. Yang J., Wu M., Gong F.* et al. Facile and controllable synthesis of solid Co3V2O8 micro-pencils as a highly efficient anode for Li-ion batteries, RSC Advances, (2017), 7, 24418 (IF: 3.1).
23. Gong F.; Bui K.; Review of Recent Developments on Using an Off-Lattice Monte Carlo Approach to Predict the Effective Thermal Conductivity of Composite Systems with Complex Structures, Nanomaterials (2016), 6, 142. (IF: 3.5).
24. Gong F.; Mesoscopic modeling of heat transfer in carbon nanotube multiphase polymer composites; AIP Conf. Proc. 1790 (2016) 150001.
25. Fang Y., Lv Y., Gong F. et al.; Synthesis of 2D-Mesoporous-Carbon/MoS2 Heterostructures with Well-Defned Interfaces for High-Performance Lithium-Ion Batteries; Advanced Materials, 42, 9385-9390 (2016). (IF: 22.0).
26. Gong F.; Papavassiliou D. V.; Duong H. M.; Inter-Carbon Nanotube Contact and Thermal Resistances in Heat Transport of Three-Phase Composites, J. Phys. Chem. C. 119 (14) 7614-7620 (2015) (IF:4.5).
27. Gong F.#; Fan Z.# Nguyen S. T.; Duong H. M; Advanced Multi-properties of Graphene Aerogel (GA) – PMMA Composites: Experiments and Modelling , Carbon, 81, 396-404 (2015). (IF: 7.1).
28. Fang Y., Lv Y., Gong F. et al. Interface Tension Induced Synthesis of Monodispersed Mesoporous Carbon Hemispheres, J. Am. Chem. Soc.,137, 2808-2811 (2015). (IF: 14.4).
29. Gong F.; Bui K.; Papavassiliou D. V.; Duong H. M.; Thermal Transport Phenomena and Limitations in Heterogeneous Polymer Composites Containing Carbon Nanotubes and Inorganic Nanoparticles, Carbon 78, 305-316 (2014). (IF: 7.1).
30. Gong F. et al. Mesoscopic Modeling of Cancer Photothermal Therapy Using Single Walled Carbon Nanotubes and Near Infrared Radiation: An Off-lattice Monte Carlo Insight, Nanotechnology 25, 205101 (2014). (IF: 3.4).
31. Gong F., Tam Y. S., Nguyen S. T., Duong H. M, Prediction of Thermal Resistances and Thermal Conductivities of Carbon Nanotube Aerogels in Various Permeated Gases, Chem. Phys. Lett., 627, (2015), 116-120 (IF: 1.8).
32. Gong F. et al. Off-lattice Monte Carlo Simulation of Heat Transfer through Carbon Nanotube Multiphase System Taking into Account Thermal Boundary Resistances, Numer. Heat Transfer Part A 65, 1023-1043 (2014). (IF: 2.4).
33. Gong F. et al. Computational Study on Anisotropic Thermal Characterization of Multi-scale Wires Using Transient Electrothermal Technique, Int. J. Therm. Sci. 77, 165-171 (2014). (IF: 3.6).
34. Wang Z. et al. Enhanced Thermal Conductivity of Segregated Poly (Vinylidene Fluoride) Composites via Forming Hybrid Conductive Network of Boron Nitride and Carbon Nanotubes, Industrial & Engineering Chemistry Research (2018), 57, 10391-10397. (IF: 3.1).