同济大学
导师风采
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高国华
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  • 副教授
  • 导师类别:硕士,博士生导师
  • 性别: 男

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  • 所属院系:物理科学与工程学院
  • 所属专业: 物理学
  • 邮箱 : gao@tongji.edu.cn
  • 工作电话 : -

个人简介

Personal Profile

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。


  • 研究方向Research Directions
纳米科学
2. 机电结构优化与控制 研究内容:在对机电结构进行分析和优化的基础上,运用控制理论进行结构参数的调整,使结构性能满足设计要求。1. 仿生结构材料拓扑优化设计, 仿生机械设计 研究内容:以仿生结构为研究对象,运用连续体结构拓扑优化设计理论和方法,对多相仿生结构(机构)材料进行2. 机电结构优化与控制 研究内容:在对机电结构进行分析和优化的基础上,运用控制理论进行结构参数的调整,使结构性能满足设计要求。1. 仿生结构材料拓扑优化设计, 仿生机械设计 研究内容:以仿生结构为研究对象,运用连续体结构拓扑优化设计理论和方法,对多相仿生结构(机构)材料进行整体布局设计。 整体布局设计。
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 CoherentPd-Pd16B3 Core-ShellElectrocatalyst 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., Fastand efficient in-situ construction of low crystalline PEDOT-intercalated V2O5nanosheets 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-entropyalloys 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 StableZinc-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., MXenesand 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 andcharacterization 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 StructuralHeterogeneity in High-Entropy Intermetallics for Electrocatalytic Upgrading ofWaste 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 ascathodes 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 convertsinactive 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-ModulusModifications: Stress-Resilient Electrode Materials for Stable Lithium-IonBatteries. 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 Synthesisof VO<sub>x</sub>@C Yolk-Shell Nanospheres and Their Application inLi-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>-richV<sub>2</sub>O<sub>5</sub>/carbon aerogelnanocomposites 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 withsolar-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 onthe 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 byCoZn<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-dominatedintermediate 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-resistant2D nanoflakes configured with super electronic networks for extraordinary fastand stable sodium-ion storage. NanoEnergy 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/ShellStructure Engineering Induces Precise Tensile Strain to Boost HydrogenEvolution Catalysis. Adv Mater 2018, 30 (26).

21.   Liang, X.;  Gao, G.;  Liu, Y.; Ge, Z.;  Leng, P.; Wu, G., Carbonnanotubes/vanadium oxide composites as cathode materials for lithium-ionbatteries. 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+-richV2O5/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 sulfidehierarchical core-shell nanosheet arrays derived from 2Dmetal-organic-frameworks for flexible asymmetric supercapacitors with ultrahighspecific capacitance and performance. JMater 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 hybridaerogels through a mixed growth and self-assembly methodology forsupercapacitors 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 SynergizingHierarchical 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 Performanceof 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 V2O5nanotubes 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 hierarchicalnanocomposites of V2O5 nanowire arrays on a three-dimensional N-doped grapheneaerogel 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 thesynthesis of graphene/V2O5 nanospheres and graphene/VN nanospheres derived froma single graphene oxide-wrapped VOx nanosphere precursor for hybridsupercapacitors. 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-splitfor 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 filmswith 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 filmscompounded 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 forHigh-Performance Supercapacitors. ACSAppl 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 ThermallyStable and Transparent WO3-SiO2 Gasochromic Films Obtained by an AutomatedPrinting 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., HybridLithographic 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 interfacialengineering of nickel tungsten carbide Janus structures for highly efficientoverall 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-Energyand Durable Supercapacitors. Small 2019, 15 (31).

38.   Zhang, K.;  Gao, G.;  Sun, W.; Liang, X.;  Liu, Y.; Wu, G., Largeinterlayer spacing vanadium oxide nanotubes as cathodes for high performancesodium 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-ElectronegativityVanadium Substitution in Cobalt Carbide Induced Enhanced Electron Transfer forEfficient Overall Water Splitting. AcsAppl 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 ofV2O5/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-structuredvanadium pentoxide thin film as a carbon- and binder-free cathode forlithium-ion battery applications. J SolidState 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 acathode for lithium ion batteries. RscAdv 2015, 5 (59), 47522-47528.

45.   Bi, W.;  Gao, G.;  Wu, Y.; Yang, H.;  Wang, J.;  Zhang, Y.; Liang, X.;  Liu, Y.; Wu, G., Novelthree-dimensional island-chain structured V2O5/graphene/MWCNT hybrid aerogelsfor 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-ShellNanospheres-Based Cathode Materials with Excellent Cycling Performance. ACS Appl Energ Mater 2020, 3 (3), 2791-2802.

47.   Liang, X.; Gao, G., Research Development of NanostructuredVanadium 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 LithiumIon Batteries. Materials Review 2018, 32 (1A), 12-33,40.

49.   Gao, G.;  Ji, M.;  Zhang, K.; Wu, G., rGO/VNTs as Cathodes forHigh 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/shellnanostructures through vacancies control and seeds growth as an outstandingsupercapacitor electrode material. Carbon2018, 132, 667-677.

51.   Wu, Y.;  Gao, G.; Wu, G.,Self-assembled three-dimensional hierarchical porous V2O5/graphene hybridaerogels 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 energyconversion efficiency zinc ion batteries. EnergyStorage 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 fromtwo-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 fromtwo-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-mediatedconstruction of Ppy@VNO/NG core-shell host targeting highly capacitive anddurable 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 andApplication to Gasochromics of WO3 Nanostructures Based on Sol-Gel Method andHydrothermal 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 V2O5nanotubes 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 vanadiumoxide 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 V2O5microspheres and their electrochemical properties. J Alloy Compd 2017, 725, 923-934.

60.   Liang, X.;  Gao, G.;  Wu, G.; Yang, H., Synthesis andcharacterization of novel hierarchical starfish-like vanadium oxide and theirelectrochemical performance. ElectrochimActa 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 V2O5microsphere 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 viaBiostructure Confinement as High-Capacity Anode Materials. Acs Appl Mater Inter 2020,12 (26), 29566-29574.

63.   Gao, G.; Wu, G., Synthesis, Structure and Electrochemical Propertiesof 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 ofOxygen 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 ofporous V2O5 yolk-shell microspheres as cathode materials for lithium ionbatteries. 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 HighHydrogen-sensing Properties. Rare MetalMat 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 onhigh-entropy alloy electrocatalysts. NatCommun 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 derivedfrom 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., WhenCubic Cobalt Sulfide Meets Layered Molybdenum Disulfide: A Core-Shell SystemToward Synergetic Electrocatalytic Water Splitting. Adv Mater 2015, 27 (32), 4752-4759.


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