王国勇

发布日期:2019-02-18 作者: 编辑:ylzzcom永利总站 点击:

 

王国勇

职称:教授

电话:13125800621

邮箱:materwanggy@jlu.edu.cn

 

 

 

  受教育经历:(从大学本科开始,按时间倒排序)

2006/09–2009/12,ylzzcom永利总站,ylzzcom永利总站,博士

2004/09–2006/06,ylzzcom永利总站,ylzzcom永利总站,硕士

2000/09–2004/06,ylzzcom永利总站,ylzzcom永利总站,学士

  研究工作经历:(按时间倒排序)

      2018/9–至今,ylzzcom永利总站,ylzzcom永利总站,教授

2012/3–2018/9,ylzzcom永利总站,ylzzcom永利总站,副教授

2009/12–2012/3,香港科技大学,机械与航空工程系,博士后

2004/09–2009/12,ylzzcom永利总站,ylzzcom永利总站,研究生

  研究方向

超级电容器和锂离子电池;自清洁表面与油水分离;金属材料力学性能

  主持项目情况

1.     国家自然科学基金青年基金,51401083,纳米晶金属室温自回复性研究,2015/01-2017/1225万元,已结题,主持

2.     吉林省科技计划项目自然科学基金,20180101071JC,高能量密度、高功率密度氧化钴基储能电极材料的研究,2018/01-2020/1215万元,在研,主持

3.     国家自然科学基金国际(地区)合作与交流项目,51761135110,仿蜘蛛丝结构的油水分离中微油滴聚集效应,2018/01-2020/12180万元,在研,骨干

4.     西安交通大学金属材料强度国家重点实验室开放课题,20141609,纳米晶金属的微观塑性变形机制及力学性能的研究,2014/05-2016/055万元,已结题,主持

5.     ylzzcom永利总站汽车材料教育部重点实验室开放课题,14-450060501456,纳米晶粒在应力和热场作用下的稳定性,2014/03-2014/125万元,已结题,主持

6.     ylzzcom永利总站引进人才(学术骨干)2012年,44万元,在研,主持

7.     ylzzcom永利总站优青培育,2015年,10万元,在研,主持

8.     温州市龙湾科技发展计划项目,2014YG09,基于高效半导体激光器的模具激光强化及修复技术开发,2013/05-2015/0320万元,已结题,主持

9.     国家自然科学基金面上项目,51371089,纳米晶金属卸载塑性变形行为及其机制的研究,2014/01-2017/1280万元,已结题,骨干

  论文发表情况

共发表第一/通讯作者论文24篇,一篇论文曾入选ESI高被引论文。 IF>8的文章5 (2Journal of Materials Chemistry A, 3ACS Applied Materials & Interfaces)8>IF>37 (2Scientific Reports1Journal of Colloid and Interface Science1Electrochimica Acta2Materials Science and Engineering A1RSC Advances)3>IF>19 (3Journal of Applied Physics 1ChemPlusChem3Journal of Materials Research1Advanced Engineering Materials1Journal of Materials Engineering and Performance)。合作文章9篇,分别发表于Acta MaterialiaJournal of the Mechanics and Physics of SolidsChemical Engineering Journal等杂志上。论文共获得包括Reviews on Advanced Materrials Science总编辑,Materials Physics and Mechanics主编Ilya Ovid'ko和英国皇家工程院院士,欧洲科学院院士,俄罗斯科学院外籍院士T.G. LangdonSCI正面引用400余次,H因子12。详细列表如下:

[1] W. Zhou, S. Li, Y. Liu, Z. Xu, S. Wei, G.Y. Wang*, J. Lian, Q. Jiang, A Dual Superlyophobic Copper Foam with Good Durability and Recyclability for High-flux, High-efficiency and Continuous Oil-Water Separation, ACS Applied Materials & Interfaces 10 (2018) 9841-9848.

[2] L. Wu, X. Leng, Y. Liu, S. Wei, C. Li, G. Wang*, J. Lian, Q. Jiang, A. Nie, T.-Y. Zhang, A Strategy for Synthesis of Nanosheets Consisting of Alternating Spinel Li4Ti5O12 and Rutile TiO2 Lamellas for High-Rate Anodes of Lithium-Ion Batteries, ACS Applied Materials & Interfaces 9(5) (2017) 4649-4657.

[3] G. Wang*, X. Leng, S. Han, Y. Shao, S. Wei, Y. Liu*, J. Lian, Q. Jiang, How to improve the stability and rate performance of lithium-ion batteries with transition metal oxide anodes, Journal of Materials Research 32(1) (2017) 16-36.

[4] X.-S. Yang, Y.-J. Wang, H.-R. Zhai, G.-Y. Wang, Y.-J. Su, L.H. Dai, S. Ogata, T.-Y. Zhang*, Time-, stress-, and temperature-dependent deformation in nanostructured copper: Creep tests and simulations, Journal of the Mechanics and Physics of Solids 94 (2016) 191-206.

[5] X.-S. Yang, Y.-J. Wang, G.-Y. Wang, H.-R. Zhai, L.H. Dai, T.-Y. Zhang*, Time, stress, and temperature-dependent deformation in nanostructured copper: Stress relaxation tests and simulations, Acta Materialia 108 (2016) 252-263.

[6] G. Wang, S. Liu, S. Wei, Y. Liu, J. Lian, Q. Jiang, Robust superhydrophobic surface on Al substrate with durability, corrosion resistance and ice-phobicity, Scientific Reports 6 (2016) 20933.

[7] Y. Liu, W. Yao, G. Wang, Y. Wang, A.S. Moita, Z. Han, L. Ren, Reversibly switchable wettability on aluminum alloy substrate corresponding to different pH droplet and its corrosion resistance, Chemical Engineering Journal 303 (2016) 565-574.

[8] X. Leng, L. Wu, Y. Liu, C. Li, S. Wei, Z. Jiang, G. Wang*, J. Lian, Q. Jiang, A novel open architecture built by ultra-fine single-crystal Co2(CO3)(OH)2 nanowires and reduced graphene oxide for asymmetric supercapacitors, Journal of Materials Chemistry A 4(43) (2016) 17171-17179.

[9] X. Leng, Y. Shao, L. Wu, S. Wei, Z. Jiang, G. Wang*, Q. Jiang, J. Lian, A unique porous architecture built by ultrathin wrinkled NiCoO2/rGO/NiCoO2 sandwich nanosheets for pseudocapacitance and Li ion storage, Journal of Materials Chemistry A 4(26) (2016) 10304-10313.

[10] X. Leng, X. Ding, J. Hu, S. Wei, Z. Jiang, J. Lian, G. Wang*, Q. Jiang, J. Liu, In situ prepared reduced graphene oxide/CoO nanowires mutually-supporting porous structure with enhanced lithium storage performance, Electrochimica Acta 190 (2016) 276-284.

[11] X. Wang, J. Hu, W. Liu, G. Wang, J. An, J. Lian*, Ni-Zn binary system hydroxide, oxide and sulfide materials: synthesis and high supercapacitor performance, Journal of Materials Chemistry A 3(46) (2015) 23333-23344.

[12] J.A. Liu, F.J. Si, D. Li, Y. Liu, Z. Cao, G.Y. Wang, EFFECT OF BATH pH ON ELECTROLESS Ni-P COATING DEPOSITED ON OPEN-CELL ALUMINUM FOAMS, Surface Review and Letters 22(6) (2015) 12.

[13] X.N. Leng, S.F. Wei, Z.H. Jiang, J.S. Lian, G.Y. Wang*, Q. Jiang, Carbon-Encapsulated Co3O4 Nanoparticles as Anode Materials with Super Lithium Storage Performance, Scientific Reports 5 (2015) 11.

[14] X. Leng, Y. Shao, S. Wei, Z. Jiang, J. Lian, G. Wang*, Q. Jiang, Ultrathin Mesoporous NiCo2O4 Nanosheet Networks as High-Performance Anodes for Lithium Storage, ChemPlusChem 80(12) (2015) 1725-1731.

[15] J.J. Hu, X.P. Zhang, G.X. Sun, G.Y. Wang*, Deformation mechanism of an electric brush-plated nanocrystalline Cu investigated by tensile testing and nanoindentation creep, Materials Research Innovations 19 (2015) S181-S186.

[16] J. Hu, G. Sun, X. Zhang, G. Wang, Z. Jiang, S. Han, J. Zhang, J. Lian, Effects of loading strain rate and stacking fault energy on nanoindentation creep behaviors of nanocrystalline Cu, Ni-20 wt.%Fe and Ni, Journal of Alloys and Compounds 647 (2015) 670-680.

[17] G. Wang, J. Lian, Q. Jiang, S. Sun, T.-Y. Zhang, High resolution transmission electron microscopic in-situ observations of plastic deformation of compressed nanocrystalline gold, Journal of Applied Physics 116(10) (2014) 103518.

[18] G. Wang, J. Lian, Dislocation Evolution in Nanograins during Successive Stress Relaxation, Advanced Engineering Materials 16(4) (2014) 413-420.

[19] S. Sun, S. Wei*, G. Wang*, Z. Jiang, J. Lian, C. Ji, The Synthesis and Electrochemical Behavior of High-Nitrogen Nickel-Free Austenitic Stainless Steel, J. of Materi Eng and Perform 23(11) (2014) 3957-3962.

[20] J. Jiang, G. Bi, G. Wang, Q. Jiang, J. Lian, Z. Jiang, Strain-hardening and warm deformation behaviors of extruded Mg–Sn–Yb alloy sheet, Journal of Magnesium and Alloys 2(2) (2014) 116-123.

[21] J. Hu, S. Han, G. Sun, S. Sun, Z. Jiang, G. Wang*, J. Lian, Effect of strain rate on tensile properties of electric brush-plated nanocrystalline copper, Materials Science and Engineering: A 618(0) (2014) 621-628.

[22] S. Han, L. Zhao, G. Wang, J. Lian, Revealing the intrinsic dislocation storage capability in nanocrystalline nickel, Materials Letters 127(0) (2014) 20-23.

[23] G.Y. Wang, J.S. Lian, T.Y. Zhang, High resolution transmission electron microscopy in situ investigation into the spontaneous coalescence of gold nanoparticles at room temperature, Rsc Advances 3(46) (2013) 24017-24020.

[24] G.Y. Wang, T.Y. Zhang, Easy Route to the Wettability Cycling of Copper Surface between Superhydrophobicity and Superhydrophilicity, Acs Applied Materials & Interfaces 4(1) (2012) 273-279.

[25] G.Y. Wang, T.Y. Zhang, Oxygen adsorption induced superhydrophilic-to-superhydrophobic transition on hierarchical nanostructured CuO surface, Journal of Colloid and Interface Science 377 (2012) 438-441.

[26] G.Y. Wang, G.Y. Li, L. Zhao, J.S. Lian, Z.H. Jiang, Q. Jiang, The origin of the ultrahigh strength and good ductility in nanotwinned copper, Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing 527(16-17) (2010) 4270-4274.

[27] G.Y. Wang, Z.H. Jiang, J.S. Lian, ENHANCED TENSILE DUCTILITY IN AN ELECTRODEPOSITED CU WITH NANO-SIZED GROWTH TWINS, International Journal of Modern Physics B 24(15-16) (2010) 2537-2542.

[28] G. Wang, J. Lian, Q. Jiang, The effect of grain size and strain rate on the tensile ductility of bulk nanostructured metals and alloys, Materials Science Forum 633-634 (2010) 393-410.

[29] L.Y. Qin, J.S. Lian, Z.H. Jiang, G.Y. Wang, Q. Jiang, Dual-phase nanocrystalline Ni-Co alloy with high strength and enhanced ductility, Journal of Materials Research 25(2) (2010) 401-405.

[30] G.Y. Wang, J.S. Lian, Z.H. Jiang, L.Y. Qin, Q. Jiang, Compressive creep behavior of an electric brush-plated nanocrystalline Cu at room temperature, Journal of Applied Physics 106(8) (2009) 086105.

[31] G.Y. Wang, Z.H. Jiang, J.S. Lian, Q. Jiang, The grain refinement mechanism of electrodeposited copper, Journal of Materials Research 24(10) (2009) 3226-3236.

[32] G.Y. Wang, Z.H. Jiang, H.Z. Zhang, J.S. Lian, Enhanced tensile ductility in an electrodeposited nanocrystalline copper, Journal of Materials Research 23(8) (2008) 2238-2244.

[33] G.Y. Wang, Z.H. Jiang, Q. Jiang, J.S. Lian, Mechanical behavior of an electrodeposited nanostructured Cu with a mixture of nanocrystalline grains and nanoscale growth twins in submicrometer grains, Journal of Applied Physics 104(8) (2008) 084305.

 

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