物理科学与工程学院-高国华导师介绍
高国华
副教授
硕,博士生导师
男
物理科学与工程学院
物理学
纳米科学
gao@tongji.edu.cn
围绕建筑节能、储能与能源转化器件领域中低成本合成与结构稳定控制、表界面结构调控、纳米功能性精准设计等科学难题和技术瓶颈,开展了氧化钨基气致变色薄膜、氧化钒基电极、高性能电催化新材料低成本合成、氧空位产生与表面修饰和构效关系的精确理论设计等工作。针对高表面纳米材料表面氧空位的精确控制,自主开发了表面氧空位控制的原位真空气相包覆设备。针对下一代建筑节能窗体,完成了气致变色智能窗系统产业化技术攻关和示范。以第一(共同)作者和通讯作者(共同)身份在Advanced Materials、Nature Communications、Advanced Functional Materials、Energy Storage Materials等国内外高影响力期刊发表SCI论文60余篇,其中包含ESI高倍引用论文2篇,ESI热门引用论文1篇,SCI他引次数达到3800余次。出版专著1部,授权国家发明专利11项。主持国家自然科学基金面上项目两项、国际合作项目一项、联合资助基金重点项目(二级课题主持)一项。
展开更多
科研项目
研究成果
1. Wen, Y.; Wang, T.; Hao, J.; Zhuang, Z.; Gao, G.; Lai, F.; Lu, S.; Wang, X.; Kang, Q.; Wu, G.; Du, M.; Zhu, H., A Coherent Pd-Pd16B3 Core-Shell Electrocatalyst for Controlled Hydrogenation in Nitrogen Reduction Reaction. Adv Funct Mater 2024, 34 (34).
2. Liu, Y.; Wang, T.; Zhang, M.; Gao, G.; Yang, J.; Cai, K., Fast and efficient in-situ construction of low crystalline PEDOT-intercalated V2O5 nanosheets for high-performance zinc-ion battery. Chem. Eng. J. 2024, 484.
3. Hao, J.; Wang, T.; Yu, R.; Cai, J.; Gao, G.; Zhuang, Z.; Kang, Q.; Lu, S.; Liu, Z.; Wu, J.; Wu, G.; Du, M.; Wang, D.; Zhu, H., Integrating few-atom layer metal on high-entropy alloys to catalyze nitrate reduction in tandem. Nat Commun 2024, 15 (1), 9020-9020.
4. Deng, S. Y.; Li, J. W.; Zewdie, G. M.; Jiang, X. D.; Ji, M. Z.; Shen, J.; Gao, G. H.; Wu, G. M.; Bao, Z. H.; Kang, H. S., Mg-Doped Porous Silicon Derived from Silica Aerogels for Fast and Stable Zinc-Ion Hybrid Capacitors with High Capacitance. Adv Funct Mater 2024, 34 (13), 11.
5. Bi, W.; Li, S.; Wang, W.; Liu, Y.; Shen, J.; Gao, G.; Zhang, Z.; Wu, G.; Cao, G., MXenes and their composites as electrodes for sodium ion batteries. Energy Storage Mater 2024, 71.
6. Sun, L.; Zheng, W.; Kang, F.; Gao, W.; Wang, T.; Gao, G.; Xu, W., On-surface synthesis and characterization of anti-aromatic cyclo 12 carbon and cyclo 20 carbon. Nat Commun 2024, 15 (1).
7. Yan, W.; Chen, J.; Wang, T.; Mateen, A.; Tang, L.; Sun, S.; Jin, C.; Li, J.; Li, H.; Chen, J.; Gao, G.; Wu, G.; Kang, H. S.; Bao, Z., Orbital interactions and high spin states: Unlocking the potential of Co-Single-Atom catalysts for Li-S batteries. Chem. Eng. J. 2024, 497.
8. Hao, J.; Wang, T.; Cai, J.; Gao, G.; Zhuang, Z.; Yu, R.; Wu, J.; Wu, G.; Lu, S.; Wang, X.; Du, M.; Wang, D.; Zhu, H., Suppression of Structural Heterogeneity in High-Entropy Intermetallics for Electrocatalytic Upgrading of Waste Plastics. Angewandte Chemie (International ed. in English) 2024, e202419369-e202419369.
9. Bi, W. C.; Gao, G. H.; Li, C.; Wu, G. M.; Cao, G. Z., Synthesis, properties, and applications of MXenes and their composites for electrical energy storage. Prog. Mater. Sci. 2024, 142, 56.
10. Yin, Q.; Wang, T. D.; Song, Z. H.; Yang, S. H.; Miao, Y. D.; Wu, Y. J.; Sui, Y. W.; Qi, J. Q.; Li, Y. Z.; Zhao, D. Y.; Gao, G. H.; Han, J. B., Computational high-throughput screening of layered double hydroxides as cathodes for chloride ion batteries. Chem. Eng. J. 2023, 459.
11. Zhu, H.; Sun, S. H.; Hao, J. C.; Zhuang, Z. C.; Zhang, S. G.; Wang, T. D.; Kang, Q.; Lu, S. L.; Wang, X. F.; Lai, F. L.; Liu, T. X.; Gao, G. H.; Du, M. L.; Wang, D. S., A high-entropy atomic environment converts inactive to active sites for electrocatalysis. Energy & Environmental Science 2023, 16 (2), 619-628.
12. Jiang, X. D.; Ji, M. Z.; Gao, G. H.; Yan, X.; Xu, Z.; Bi, W. C.; Cheng, Q.; Wu, G. M., High-Modulus Modifications: Stress-Resilient Electrode Materials for Stable Lithium-Ion Batteries. Phys Rev Appl 2023, 20 (2).
13. Ji, M. Z.; Ni, J.; Liang, X.; Cheng, Q.; Gao, G. H.; Wu, G. M.; Xiao, Q. F., Biomimetic Synthesis of VO<sub>x</sub>@C Yolk-Shell Nanospheres and Their Application in Li-S Batteries. Adv Funct Mater 2022, 32 (48), 12.
14. Bi, W. C.; Deng, S. Y.; Tang, H. S.; Liu, Y.; Shen, J.; Gao, G. H.; Wu, G. M.; Atif, M.; AlSalhi, M. S.; Gao, G. Z., Coherent V<SUP>4+</SUP>-rich V<sub>2</sub>O<sub>5</sub>/carbon aerogel nanocomposites for high performance supercapacitors. Sci China Mater 2022, 65 (7), 1797-1804.
15. Dou, Y. B.; Yao, Y. C.; Wu, G. G.; Gao, G. H.; Zatloukal, M.; Hélix-Nielsen, C.; Zhang, W. J., A defect-rich layered double hydroxide nanofiber filter with solar-driven regeneration for wastewater treatment. Chem. Eng. J. 2022, 430, 9.
16. Bi, W. C.; Jiang, X. D.; Li, C.; Liu, Y.; Gao, G. H.; Wu, G. M.; Atif, M.; AlSalhi, M.; Cao, G. Z., Effects of Valence States of Working Cations on the Electrochemical Performance of Sodium Vanadate. Acs Appl Mater Inter 2022, 14 (17), 19714-19724.
17. Yuan, F.; Gao, G. H.; Jiang, X. D.; Bi, W. C.; Su, Y. X.; Guo, J. W.; Bao, Z. H.; Shen, J.; Wu, G. M., Suppressing the metal-metal interaction by CoZn<sub>0.5</sub>V<sub>1.5</sub>O<sub>4</sub> derived from two-dimensional metal-organic frameworks for supercapacitors. Sci China Mater 2022, 65 (1), 105-114.
18. Hao, J. C.; Zhuang, Z. C.; Cao, K. C.; Gao, G. H.; Wang, C.; Lai, F. L.; Lu, S. L.; Ma, P. M.; Dong, W. F.; Liu, T. X.; Du, M. L.; Zhu, H., Unraveling the electronegativity-dominated intermediate adsorption on high-entropy alloy electrocatalysts. Nat Commun 2022, 13 (1).
19. Guo, M.; Wang, J.; Dou, H.; Gao, G.; Wang, S.; Wang, J.; Xiao, Z.; Wu, G.; Yang, X.; Ma, Z.-F., Agglomeration-resistant 2D nanoflakes configured with super electronic networks for extraordinary fast and stable sodium-ion storage. Nano Energy 2019, 56, 502-511.
20. Zhu, H.; Gao, G.; Du, M.; Zhou, J.; Wang, K.; Wu, W.; Chen, X.; Li, Y.; Ma, P.; Dong, W.; Duan, F.; Chen, M.; Wu, G.; Wu, J.; Yang, H.; Guo, S., Atomic-Scale Core/Shell Structure Engineering Induces Precise Tensile Strain to Boost Hydrogen Evolution Catalysis. Adv Mater 2018, 30 (26).
21. Liang, X.; Gao, G.; Liu, Y.; Ge, Z.; Leng, P.; Wu, G., Carbon nanotubes/vanadium oxide composites as cathode materials for lithium-ion batteries. J Sol-Gel Sci Techn 2017, 82 (1), 224-232.
22. Bi, W.; Deng, S.; Tang, H.; Liu, Y.; Shen, J.; Gao, G.; Wu, G.; Atif, M.; AlSalhi, M. S.; Gao, G., Coherent V4+-rich V2O5/carbon aerogel nanocomposites for high performance supercapacitors. Sci China Mater 2022, 65 (7), 1797-1804.
23. Sun, W.; Du, Y.; Wu, G.; Gao, G.; Zhu, H.; Shen, J.; Zhang, K.; Cao, G., Constructing metallic zinc-cobalt sulfide hierarchical core-shell nanosheet arrays derived from 2D metal-organic-frameworks for flexible asymmetric supercapacitors with ultrahigh specific capacitance and performance. J Mater Chem A 2019, 7 (12), 7138-7150.
24. Wu, Y.; Gao, G.; Yang, H.; Bi, W.; Liang, X.; Zhang, Y.; Zhang, G.; Wu, G., Controlled synthesis of V2O5/MWCNT core/shell hybrid aerogels through a mixed growth and self-assembly methodology for supercapacitors with high capacitance and ultralong cycle life. J Mater Chem A 2015, 3 (30), 15692-15699.
25. Guo, M.; Zhao, W.; Dou, H.; Gao, G.; Zhao, X.; Yang, X., Decreasing Ion-Diffusion Barrier Enables Superior Na-Ion Storage by Synergizing Hierarchical Architecture and Lattice Distortion. Acs Appl Mater Inter 2019, 11 (30), 27024-27032.
26. Bi, W.; Jiang, X.; Li, C.; Liu, Y.; Gao, G.; Wu, G.; Atif, M.; AlSalhi, M.; Cao, G., Effects of Valence States of Working Cations on the Electrochemical Performance of Sodium Vanadate. Acs Appl Mater Inter 2022, 14 (17), 19714-19724.
27. Liu, Y.; Guan, D.; Gao, G.; Liang, X.; Sun, W.; Zhang, K.; Bi, W.; Wu, G., Enhanced electrochemical performance of electrospun V2O5 nanotubes as cathodes for lithium ion batteries. J Alloy Compd 2017, 726, 922-929.
28. Sun, W.; Gao, G.; Du, Y.; Zhang, K.; Wu, G., A facile strategy for fabricating hierarchical nanocomposites of V2O5 nanowire arrays on a three-dimensional N-doped graphene aerogel with a synergistic effect for supercapacitors. J Mater Chem A 2018, 6 (21), 9938-9947.
29. Sun, W.; Ji, X.; Gao, G.; Wu, G., A facile strategy for the synthesis of graphene/V2O5 nanospheres and graphene/VN nanospheres derived from a single graphene oxide-wrapped VOx nanosphere precursor for hybrid supercapacitors. Rsc Adv 2018, 8 (49), 27924-27934.
30. Wang, H.; Gao, G.; Wu, G.; Zhao, H.; Qi, W.; Chen, K.; Zhang, W.; Li, Y., Fast hydrogen diffusion induced by hydrogen pre-split for gasochromic based optical hydrogen sensors. Int J Hydrogen Energ 2019, 44 (29), 15665-15676.
31. Qi, W.; Gao, G.; Wu, G.; Wang, H., Flexible gasochromic films with favorable high temperature resistance and energy efficiency. Sol Energ Mat Sol C 2019, 195, 63-70.
32. Zhang, Z.; Guan, D.; Gao, G.; Wu, G.; Wang, H., Gasochromic properties of novel tungsten oxide thin films compounded with methyltrimethoxysilane (MTMS). Rsc Adv 2017, 7 (65), 41289-41296.
33. Bi, W.; Wu, Y.; Liu, C.; Wang, J.; Du, Y.; Gao, G.; Wu, G.; Cao, G., Gradient Oxygen Vacancies in V2O5/PEDOT Nanocables for High-Performance Supercapacitors. ACS Appl Energ Mater 2019, 2 (1), 668-677.
34. Gao, G.; Xue, S.; Wang, H.; Zhang, Z.; Wu, G.; Debela, T. T.; Kang, H. S., Highly Thermally Stable and Transparent WO3-SiO2 Gasochromic Films Obtained by an Automated Printing Method. ACS Sustain. Chem. Eng. 2021, 9 (51), 17319-17329.
35. Wang, J.; Ji, Z.; Xu, X.; Chen, T.; Chen, B.; Gao, G.; Ma, J.; Nie, X.; Xu, X., Hybrid Lithographic Arbitrary Patterning of TiO2 Nanorod Arrays. ACS Omega 2022, 7 (25), 22039-22045.
36. Zhang, S.; Gao, G.; Zhu, H.; Cai, L.; Jiang, X.; Lu, S.; Duan, F.; Dong, W.; Chai, Y.; Du, M., In situ interfacial engineering of nickel tungsten carbide Janus structures for highly efficient overall water splitting. Sci Bull 2020, 65 (8), 640-650.
37. Bi, W.; Wang, J.; Jahrman, E. P.; Seidler, G. T.; Gao, G.; Wu, G.; Cao, G., Interface Engineering V2O5 Nanofibers for High-Energy and Durable Supercapacitors. Small 2019, 15 (31).
38. Zhang, K.; Gao, G.; Sun, W.; Liang, X.; Liu, Y.; Wu, G., Large interlayer spacing vanadium oxide nanotubes as cathodes for high performance sodium ion batteries. Rsc Adv 2018, 8 (39), 22053-22061.
39. Zhang, S.; Gao, G.; Hao, J.; Wang, M.; Zhu, H.; Lu, S.; Duan, F.; Dong, W.; Du, M.; Zhao, Y., Low-Electronegativity Vanadium Substitution in Cobalt Carbide Induced Enhanced Electron Transfer for Efficient Overall Water Splitting. Acs Appl Mater Inter 2019, 11 (46), 43261-43269.
40. Gao, G.; Xue, S.; Wang, H.; Zhang, Z.; Shen, J.; Wu, G., Medium-scale production of gasochromic windows by sol-gel. J Sol-Gel Sci Techn 2022.
41. Liu, Y.; Gao, G.; Liang, X.; Wu, G., Nanofibers of V2O5/C@MWCNTs as the cathode material for lithium-ion batteries. J Solid State Electr 2018, 22 (8), 2385-2393.
42. Xue, S.; Gao, G.; Zhang, Z.; Jiang, X.; Shen, J.; Wu, G.; Dai, H.; Xu, Y.; Xiao, Y., Nanoporous WO3 Gasochromic Films for Gas Sensing. Acs Applied Nano Materials 2021, 4 (8), 8368-8375.
43. Zeng, Y.; Gao, G.; Wu, G.; Yang, H., Nanosheet-structured vanadium pentoxide thin film as a carbon- and binder-free cathode for lithium-ion battery applications. J Solid State Electr 2015, 19 (11), 3319-3328.
44. Wang, J.; Cui, C.; Gao, G.; Zhou, X.; Wu, J.; Yang, H.; Li, Q.; Wu, G., A new method to prepare vanadium oxide nano-urchins as a cathode for lithium ion batteries. Rsc Adv 2015, 5 (59), 47522-47528.
45. Bi, W.; Gao, G.; Wu, Y.; Yang, H.; Wang, J.; Zhang, Y.; Liang, X.; Liu, Y.; Wu, G., Novel three-dimensional island-chain structured V2O5/graphene/MWCNT hybrid aerogels for supercapacitors with ultralong cycle life. Rsc Adv 2017, 7 (12), 7179-7187.
46. Liang, X.; Gao, G.; Jiang, X.; Zhang, W.; Bi, W.; Wang, J.; Du, Y.; Wu, G., Preparation of Hydrophobic PPy Coated V2O5 Yolk-Shell Nanospheres-Based Cathode Materials with Excellent Cycling Performance. ACS Appl Energ Mater 2020, 3 (3), 2791-2802.
47. Liang, X.; Gao, G., Research Development of Nanostructured Vanadium Oxide as Cathodes for Lithium-ion Batteries. Materials Review 2015, 29 (7A), 1-11,33.
48. Liang, X.; Gao, G.; Wu, G., Research Development of Vanadium Oxide Serving as Cathode Materials for Lithium Ion Batteries. Materials Review 2018, 32 (1A), 12-33,40.
49. Gao, G.; Ji, M.; Zhang, K.; Wu, G., rGO/VNTs as Cathodes for High Performance Sodium Ion Batteries with Good Cycling Performance. Electronic Materials Letters 2022, 18 (1), 47-56.
50. Sun, W.; Gao, G.; Zhang, K.; Liu, Y.; Wu, G., Self-assembled 3D N-CNFs/V2O5 aerogels with core/shell nanostructures through vacancies control and seeds growth as an outstanding supercapacitor electrode material. Carbon 2018, 132, 667-677.
51. Wu, Y.; Gao, G.; Wu, G., Self-assembled three-dimensional hierarchical porous V2O5/graphene hybrid aerogels for supercapacitors with high energy density and long cycle life. J Mater Chem A 2015, 3 (5), 1828-1832.
52. Bi, W.; Gao, G.; Wu, G.; Atif, M.; AlSalhi, M. S.; Cao, G., Sodium vanadate/PEDOT nanocables rich with oxygen vacancies for high energy conversion efficiency zinc ion batteries. Energy Storage Mater 2021, 40, 209-218.
53. Yuan, F.; Gao, G.; Jiang, X.; Bi, W.; Su, Y.; Guo, J.; Bao, Z.; Shen, J.; Wu, G., Suppressing the metal-metal interaction by CoZn0.5V1.5O4 derived from two-dimensional metal-organic frameworks for supercapacitors. Sci China Mater 2021.
54. Yuan, F.; Gao, G.; Jiang, X.; Bi, W.; Su, Y.; Guo, J.; Bao, Z.; Shen, J.; Wu, G., Suppressing the metal-metal interaction by CoZn0.5V1.5O4 derived from two-dimensional metal-organic frameworks for supercapacitors. Sci China Mater 2022, 65 (1), 105-114.
55. Sun, W.; Gao, G.; Wu, G.; You, Z., Surface-oxidation-mediated construction of Ppy@VNO/NG core-shell host targeting highly capacitive and durable negative electrode for supercapacitors. Sci China Mater 2021, 64 (9), 2148-2162.
56. Zhang, Z.; Gao, G.; Wang, H.; Wu, G.; Shen, J.; Zhou, B.; Zhang, Z., Synthesis and Application to Gasochromics of WO3 Nanostructures Based on Sol-Gel Method and Hydrothermal Process. Rare Metal Mat Eng 2016, 45, 354-359.
57. Liang, X.; Gao, G.; Feng, S.; Du, Y.; Wu, G., Synthesis and characterization of carbon supported V2O5 nanotubes and their electrochemical properties. J Alloy Compd 2019, 772, 429-437.
58. Liang, X.; Gao, G.; Liu, Y.; Zhang, T.; Wu, G., Synthesis and characterization of Fe-doped vanadium oxide nanorods and their electrochemical performance. J Alloy Compd 2017, 715, 374-383.
59. Liang, X.; Gao, G.; Wu, G., Synthesis and characterization of hollow and core-shell structured V2O5 microspheres and their electrochemical properties. J Alloy Compd 2017, 725, 923-934.
60. Liang, X.; Gao, G.; Wu, G.; Yang, H., Synthesis and characterization of novel hierarchical starfish-like vanadium oxide and their electrochemical performance. Electrochim Acta 2016, 188, 625-635.
61. Liang, X.; Gao, G.; Du, Y.; Wang, J.; Sun, W.; Liu, Y.; Zhang, K.; Wu, G., Synthesis and characterization of various V2O5 microsphere structures and their electrochemical performance. J Alloy Compd 2018, 757, 177-187.
62. Cen, D.; Ding, Y.; Wei, R.; Huang, X.; Gao, G.; Wu, G.; Mei, Y.; Bao, Z., Synthesis of Metal Oxide/Carbon Nanofibers via Biostructure Confinement as High-Capacity Anode Materials. Acs Appl Mater Inter 2020, 12 (26), 29566-29574.
63. Gao, G.; Wu, G., Synthesis, Structure and Electrochemical Properties of Vo(x) Nanosheets Prepared from V2O5 and Carbon Aerogels. Rare Metal Mat Eng 2016, 45, 315-319.
64. Bi, W.; Jahrman, E.; Seidler, G.; Wang, J.; Gao, G.; Wu, G.; Atif, M.; AlSalhi, M.; Cao, G., Tailoring Energy and Power Density through Controlling the Concentration of Oxygen Vacancies in V2O5/PEDOT Nanocable-Based Supercapacitors. Acs Appl Mater Inter 2019, 11 (18), 16647-16655.
65. Dou, Y.; Liang, X.; Gao, G.; Wu, G., Template-free synthesis of porous V2O5 yolk-shell microspheres as cathode materials for lithium ion batteries. J Alloy Compd 2018, 735, 109-116.
66. Wang, Q.; Liang, X.; Liu, B.; Song, Y.; Gao, G.; Xu, X., Thermal conductivity of V2O5 nanowires and their contact thermal conductance. Nanoscale 2020, 12 (2), 1138-1143.
67. Wang, H.; Gao, G.; Wu, G.; Zhang, Z.; Shen, J.; Zhou, B., TiO2-doped WO3 Gasochromic Thin Films Produced by Sol-Gel Technique with High Hydrogen-sensing Properties. Rare Metal Mat Eng 2016, 45, 325-331.
68. Hao, J.; Zhuang, Z.; Cao, K.; Gao, G.; Wang, C.; Lai, F.; Lu, S.; Ma, P.; Dong, W.; Liu, T.; Du, M.; Zhu, H., Unraveling the electronegativity-dominated intermediate adsorption on high-entropy alloy electrocatalysts. Nat Commun 2022, 13 (1).
69. Bi, W.; Huang, J.; Wang, M.; Jahrman, E. P.; Seidler, G. T.; Wang, J.; Wu, Y.; Gao, G.; Wu, G.; Cao, G., V2O5-Conductive polymer nanocables with built-in local electric field derived from interfacial oxygen vacancies for high energy density supercapacitors. J Mater Chem A 2019, 7 (30), 17966-17973.
70. Zhu, H.; Zhang, J.; Yanzhang, R.; Du, M.; Wang, Q.; Gao, G.; Wu, J.; Wu, G.; Zhang, M.; Liu, B.; Yao, J.; Zhang, X., When Cubic Cobalt Sulfide Meets Layered Molybdenum Disulfide: A Core-Shell System Toward Synergetic Electrocatalytic Water Splitting. Adv Mater 2015, 27 (32), 4752-4759.
展开更多
学校介绍
同济大学是国家教育部直属重点大学,也是首批被批准成立研究生院、并被列为国家“ 211 工程”和“面向 21 世纪教育振兴行动计划”(985 工程)与上海市重点建设的高水平研究型大学之一。同济大学创建于 1907 年,现已成为拥有理、工、医、文、法、经(济)、管(理)、哲、教(育)9 大门类的研究型、综合性、多功能的现代大学。
同济大学现设有各类专业学院 22 个,还建有继续教育学院、 职业技术教育学院等,设有经中德政府批准合作培养硕士研究生的中德学院、中德工程学院,与法国巴黎高科大学集团合作举办的中法工程和管理学院等。目前学校共有 81 个本科专业、 140 个硕士点、 7 个硕士专业学位授权点、博士授权点 58 个、 13 个博士后流动站,学校拥有国家级重点学校 10 个。各类学生 5 万多人,教学科研人员 4200 多人,其中有中科院院士 6 人、工程院院士 7 人,具有各类高级职称者 1900 多人,拥有长江学者特聘教授岗位 22 个。作为国家重要的科研中心之一,学校设有国家、省部级重点实验室和工程研究中心等国家科研基地 16 个。学校还设有附属医院和 2 所附属学校。
近年来同济大学正在探索并逐步形成有自己特色的现代教育思想和办学理念。以本科教育为立校之本,以研究生教育为强校之路。确立“知识、能力、人格”三位一体的全面素质教育和复合型人才培养模式。坚持“人才培养、科学研究、社会服务、国际交往”四大办学功能协调发展,努力强化服务社会的功能,实现大学功能中心化。以国家科技发展战略和地区经济重点需求为指针,促进传统学科高新化、新兴学科强势化、学科交叉集约化。与产业链紧密结合,形成优势学科和相对弱势学科互融共进的学科链和学科群,构建综合性大学的学科体系,其中桥梁工程、海洋地质、城市规划、结构工程、道路交通、车辆工程、环境工程等学科在全国居领先地位。在为国家经济建设和社会发展做贡献的过程中,争取更多的“单项冠军”,提升学校的学术地位和社会声誉。学校正努力建设文理交融、医工结合、科技教育与人文教育协调发展的综合性、研究型、国际知名高水平大学。
同济大学已建成的校园占地面积 3700 多亩,分五个校区,四平路校区位于上海市四平路,沪西校区位于上海市真南路,沪北校区位于上海市共和新路,沪东校区位于上海市武东路。正在建设中的嘉定校区位于安亭上海国际汽车城内。
同济大学研究生院简介
同济大学一贯重视研究生教育,早在 20 世纪 50 年代初即在部分专业招收培养研究生。 1978 年学校恢复招收硕士研究生, 1981 年起招收博士研究生,同年被国务院学位委员会批准为首批有权授予博士、硕士学位的单位。 1986 年经国务院批准试办研究生院, 1996 年经评估正式成立研究生院,成为我国培养高层次专门人才的重要基地之一。同济大学现有一级学科博士学位授权点 12 个,二级学科博士学位授权点 68 个(含自主设置 10 个二级学科博士点),硕士学位授权点 147 个(含自主设置 7 个二级学科硕士点),分属哲学、经济学、法学、教育学、文学、理学、工学、医学、管理学等 9 个学科门类。其中土木工程、建筑学、交通运输工程、海洋科学、环境科学与工程、力学、材料科学与工程等学科处在全国优势和领先地位,机电、管理、理学等学科近年有了长足进展。我校还设有 13 个博士后科研流动站。近些年来,为了适应我国经济建设和社会发展的需要,学校还十分注重培养不同类型、多个层次、多种规格的高层次专门人才。学校既设科学学位,又设工商管理、行政管理、建筑学、临床医学、工程硕士(含 21 个工程领域)、口腔医学等多种专业学位;既培养学术型、研究型研究生,又培养应用型、复合型专业学位研究生;既有在校全日制攻读学位模式,又有在职人员攻读专业硕士学位或以同等学力申请硕士学位、中职教师在职攻读硕士学位、高校教师在职攻读硕士学位模式。此外,还面向社会举办多种专业研究生课程进修班等,充分发挥了我校学科优势和特色,由此形成了多渠道、多规格、多层次的办学模式,取得了良好的社会效益。
同济大学研究生院是校长领导下具有相对独立职能的研究生教学和行政管理机构,下设招生办公室、管理处、培养处、学位办公室、学科建设办公室和行政办公室。同时,学校党委还专门设立了研究生工作部。学校设有校学位评定委员会,各学院有学位评定分委员会,并设立了各学科、专业委员会,配有学位管理工作秘书、教务员、班主任、研究生教学秘书等教辅人员。研究生院曾多次被评为全国和上海市学位与研究生教育管理工作先进集体。
二十多年来,同济大学始终把全面提高培养质量作为研究生教育改革的指导思想,在严格质量管理方面采取了一系列切实有效的措施,取得了较好效果。在连续多年全国百篇优秀博士学位论文评选中,有 7 篇入选。同济大学为国家培养了一大批高素质的高级专门人才,至今已授予博士学位 1311 人,硕士学位近 9504 人,其中有相当一部分已成为我国社会主义现代化建设的重要骨干力量。至 2004 年 9 月,在校博士、硕士研究生约达 11000 多人,专业学位硕士生约 2700 人。根据本校研究生教育发展规划, 2006 年计划招收博士生、硕士生(含专业学位研究生)超过 4000 名。同济大学正在为我国经济建设和社会发展输送高层次人才做出更大的贡献。
展开更多
同济大学硕士研究生学费及奖助政策
收费和奖励
1) 按照国务院常务会议精神,从 2014 年秋季学期起,向所有纳入国家招生计划的新入学研究生收取学费。其中:工程管理硕士(125600)、MBA[微博](125100)、MPA(125200)、法律硕士(非法学)(035101)、软件工程领域工程硕士(085212)、金融硕士(025100)、会计硕士(125300)、翻译硕士(055101、055109)、护理硕士(105400)、教育硕士(045100)、汉语国际教育硕士(045300)、人文学院(210)的艺术硕士(135108)专业学位研究生的学费标准另行公布,其它硕士研究生学费不超过 8000 元/学年。
2) 对非定向就业学术型研究生和非定向就业专业学位硕士研究生,同济大学有完善的奖励体系(工程管理硕士(125600)、MBA(125100)、MPA(125200)、法律硕士(非法学)(035101)、软件工程硕士(085212)、金融硕士(025100)、会计硕士(125300)、翻译硕士(055101、055109)、护理硕士(105400)、教育硕士(045100)、汉语国际教育硕士(045300)、人文学院(210)的艺术硕士(135108)的奖励由培养单位另行制订)。对亍纳入奖励体系的非定向就业学术型硕士生和非定向就业专业学位硕士生在入学时全部都可以获得 8000 元/学年的全额学业奖学金,该奖学金用以抵充学费。对纳入奖励体系的硕士研究生还可获得不少亍 600 元/月的励学金,每年发放10 个月。另外,纳入奖励体系的非定向就业研究生都可以申请励教和励管的岗位,获得额外的资励。所有非定向就业硕士研究生在学期间纳入上海市城镇居民基本医疗保险,可申请办理国家励学贷款,可参加有关专项奖学金评定。
3)工商管理硕士在职班、金融硕士在职班、公共管理硕士、工程管理硕士、会计硕士、护理硕士、教育硕士、汉语国际教育硕士、人文学院的艺术硕士采取在职学习方式,考生录取后,人事关系不人事档案不转入学校,在读期间不参加上海市大学生医疗保障,学校不安排住宿,毕业时不纳入就业计划。
展开更多