代表性成果

发布时间:2018-3-27 10:59:13

2.1.1 代表性专利

[1].Xiaodong Han, Pan Liu, YonghaiYue, Ze Zhang, Sensor for quantitative measurement of electromechanicalproperties and microstructure of nano-materials and method for making the same,US Patent No. US8302494

[2].Xiaodong Han, Yonghai Yue, YuefeiZhang, Pan Liu, Kun Zheng, Xiaodong Wang, Ze Zhang, Double tilt transmissionelectron microscope sample holder for In-situ measurement of microstructures, US Patent No. 8569714

[3].Xiaodong Han, Pan Liu, YuefeiZhang, Yonghai Yue, Ze Zhang, Device and method for measuring electromechanicalproperties and microstructure of nano-materials under stress state, US patent, US Patent No. 8069733

[4].韩晓东,岳永海,张泽,透過型電子顕微鏡で二軸傾く転の元力、電気性能総合テストサンプルレバー,Japanese Patent No. JP5394596

[5].韩晓东,翟亚迪,毛圣成,王晓冬,张剑飞,李志鹏,孙世铎,张韬楠,蔡吉祥,王丽,吉元,张泽 , 一种透射电子显微镜用双轴倾转样品台,中国发明专利,专利号:ZL 201510081273.8

[6].韩晓东,张跃飞,张泽,一种热双金属片驱动的透射电子显微镜载网,中国发明专利,专利号:ZL200610144031.X

[7].韩晓东,张跃飞,张泽,单根纳米线原位力学性能测试和结构分析的方法及其装置,中国发明专利,专利号:ZL200610057989.5

[8].韩晓东,岳永海,张跃飞,张泽,一种纳米材料原位结构性能测试的透射电镜载片,中国发明专利,专利号:ZL200710122092.0

[9].韩晓东,郑坤,张泽,一种透射电镜中纳米线原位拉伸下力电性能测试装置,中国发明专利,专利号:200710119316.2

[10].韩晓东,郑坤,张泽,透射电镜中纳米线原位压缩下力电性能测试装置,中国发明专利,专利号:ZL200710119315.8

[11].韩晓东,郑坤,张泽,透射电镜中纳米线原位压缩下力电性能测试装置,中国发明专利,专利号:200710119315.8

[12].韩晓东,张跃飞,张泽,扫描电镜中纳米线原位拉伸装置及方法,中国发明专利,专利号:200610169839.3

[13].张泽,王珂,刘攀,韩晓东,一种基于相变材料的透射电镜电学测量载网,中国发明专利,专利号:200810056408.5

[14].韩晓东,岳永海,郑坤,张跃飞,张泽,透射电镜用纳米材料应力测试载网, 中国发明专利,专利号:ZL200810056836.8

[15].韩晓东,岳永海,张跃飞,张泽,低维材料应力状态下性能测试装置,中国发明专利,专利号:ZL200810239234.6

[16].韩晓东,岳永海,郑坤,张跃飞,张泽,压电陶瓷片驱动的扫描电镜中纳米材料拉伸装置,中国发明专利,专利号:ZL200810056837.2

[17].韩晓东,刘攀,张跃飞,邓青松,张泽,透射电镜用非磁性双金属片驱动器,中国发明专利,专利号:ZL200910086803.2

[18].韩晓东,刘攀,张泽,透射电镜用力电性能与显微结构测量的传感器及制作方法,中国发明专利,专利号:ZL200910209565.X

[19].韩晓东,刘攀,岳永海,张泽,定量测试力电性能与显微结构的传感器及制作方法,中国发明专利,专利号:ZL200910209434.1

[20].韩晓东,刘攀,张泽,低维纳米材料显微结构与电学性能测试装置和方法,中国发明专利,专利号:ZL200910084260.0

[21].韩晓东,刘攀,张跃飞,邓青松,张泽,透射电镜用非磁性双金属片驱动器,中国发明专利,专利号:ZL200910086803.2

[22].韩晓东,岳永海,张泽,用于透射电镜的原位力、电性能单轴拉伸样品杆,中国发明专利,专利号:ZL201110169007.2

[23].韩晓东,岳永海,张泽,一种研究材料特定温度下力学性能原位TEM拉伸台,中国发明专利,专利号:ZL201210228812.2

[24].毛圣成,臧科涛,王晓冬,韩晓东,李海鑫,孙世铎,向思思,张泽,一种透射电镜用基于形状记忆效应的原位单轴拉伸变形装置中国发明专利,专利号:ZL201410109395.9


2.1.2 代表性文章

[1].Z. Zhang,X.D. Han. Microscopy sparks development, Nature Materials 15 (2016) 695-697

[2].L. Wang,J. Teng, P. Liu, A. Hirata, E. Ma, Z. Zhang, M. Chen, X. Han. Grain rotationmediated by grain boundary dislocations in nanocrystalline platinum, NatureCommunications 5 (2014) 4402

[3].L.H.Wang, P. Liu, P.F. Guan, M.J. Yang, J.L. Sun, Y.Q. Cheng, A. Hirata, Z. Zhang,E. Ma, M.W. Chen, X.D. Han. In situ atomic-scale observation of continuous andreversible lattice deformation beyond the elastic limit, Nature Communications 4 (2013) 2413

[4].K. Zheng,C.C. Wang, Y.Q. Cheng, Y.H. Yue, X.D. Han, Z. Zhang, Z.W. Shan, S.X. Mao, M.M.Ye, Y.D. Yin, E. Ma. Electron-beam-assisted superplastic shaping of nanoscaleamorphous silica, Nature Communications 1 (2010) 24

[5].L.H.Wang, Z. Zhang, X.D. Han. In situ experimental mechanics of nanomaterials atthe atomic scale, Npg Asia Materials 5 (2013) e40

[6].X.D. Han,K. Zheng, Y.F. Zhang, X.N. Zhang, Z. Zhang, Z.L. Wang. Low-temperature in sitularge-strain plasticity of silicon nanowires, Advanced Materials 19 (2007) 2112

[7].X.D. Han,Y.F. Zhang, K. Zheng, X.N. Zhang, Z. Zhang, Y.J. Hao, X.Y. Guo, J. Yuan, Z.L.Wang. Low-temperature in situ large strain plasticity of ceramic SiC nanowiresand its atomic-scale mechanism, Nano Letters 7 (2007) 452

[8].B. Wei,K. Zheng, Y. Ji, Y.F. Zhang, Z. Zhang, X.D. Han. Size-Dependent BandgapModulation of ZnO Nanowires by Tensile Strain, Nano Letters 12 (2012) 4595

[9].Y.F.Zhang, X.D. Han, K. Zheng, Z. Zhang, X.N. Zhang, J.Y. Fu, Y. Ji, Y.J. Hao, X.Y.Guo, Z.L. Wang. Direct observation of super-plasticity of beta-SiC nanowires atlow temperature, Advanced Functional Materials 17 (2007) 3435

[10].L.H.Wang, X.D. Han, P. Liu, Y.H. Yue, Z. Zhang, E. Ma. In Situ Observation ofDislocation Behavior in Nanometer Grains, Physical Review Letters 105 (2010) 135501

[11].P. Liu,S.C. Mao, L.H. Wang, X.D. Han, Z. Zhang. Direct dynamic atomic mechanisms of strain-inducedgrain rotation in nanocrystalline, textured, columnar-structured thin goldfilms, ScriptaMaterialia 64 (2011) 343

[12].K. Zheng,X.D. Han, L.H. Wang, Y.F. Zhang, Y.H. Yue, Y. Qin, X.N. Zhang, Z. Zhang. AtomicMechanisms Governing the Elastic Limit and the Incipient Plasticity of BendingSi Nanowires, NanoLetters 9 (2009) 2471

[13].Y.H. Yue,P. Liu, Z. Zhang, X.D. Han, E. Ma. Approaching the Theoretical Elastic StrainLimit in Copper Nanowires, Nano Letters 11 (2011) 3151

[14].Y.H. Yue,P. Liu, Q.S. Deng, E. Ma, Z. Zhang, X.D. Han. Quantitative Evidence ofCrossover toward Partial Dislocation Mediated Plasticity in Copper SingleCrystalline Nanowires, Nano Letters 12 (2012) 4045

[15].Y.H. Yue,N.K. Chen, X.B. Li, S.B. Zhang, Z. Zhang, M.W. Chen, X.D. Han. CrystallineLiquid and Rubber-Like Behavior in Cu Nanowires, Nano Letters 13 (2013) 3812

[16].L.H.Wang, K. Zheng, Z. Zhang, X.D. Han. Direct Atomic-Scale Imaging about theMechanisms of Ultralarge Bent Straining in Si Nanowires, Nano Lett 11 (2011) 2382-2385.

[17].L.H. Wang,Y. Lu, D.L. Kong, L.R. Xiao, X.C. Sha, J.L. Sun, Z. Zhang, X.D. Han. Dynamicand atomic-scale understanding of the twin thickness effect on dislocationnucleation and propagation activities by in situ bending of Ni nanowires, Acta Materialia90 (2015) 194

[18].L.H.Wang, X.D. Han, Y.F. Zhang, K. Zheng, P. Liu, Z. Zhang. Asymmetrical quantumdot growth on tensile and compressive-strained ZnO nanowire surfaces, Acta Materialia59 (2011) 651

[19].Q.S.Deng, Y.Q. Cheng, Y.H. Yue, L. Zhang, Z. Zhang, X.D. Han, E. Ma. Uniformtensile elongation in framed submicron metallic glass specimen in the limit ofsuppressed shear banding, Acta Materialia 59 (2011) 6511

[20].L. Wang,Y. Ji, B. Wei, Y.Q. Zhang, J.Y. Fu, X.D. Xu, X.D. Han. Charge compensation byin-situ heating for insulating ceramics in scanning electron microscope, Ultramicroscopy109 (2009) 1326

[21].X.D. Han,L.H. Wang, Y.H. Yue, Z. Zhang. In situ atomic scale mechanical microscopydiscovering the atomistic mechanisms of plasticity in nano-single crystals andgrain rotation in polycrystalline metals, Ultramicroscopy 151 (2015) 94

[22].Y. Lu,S.S. Xiang, L.R. Xiao, L.H. Wang, Q.S. Deng, Z. Zhang, X.D. Han. Dislocation"Bubble-Like-Effect" and the Ambient Temperature Super-plasticElongation of Body-centred Cubic Single Crystalline Molybdenum, ScientificReports 6 (2016) 22937

[23].R.W.Shao, K. Zheng, B. Wei, Y.F. Zhang, Y.J. Li, X.D. Han, Z. Zhang, J. Zou.Bandgap engineering and manipulating electronic and optical properties of ZnOnanowires by uniaxial strain, Nanoscale 6 (2014) 4936

[24].X.D. Han,S.L. Zheng, Y.F. Zhang, K. Zheng, S.B. Zhang, Z. Zhang, X.N. Zhang, X.Q. Liu,G. Chen, Y.J. Hao, X.Y. Guo. Polarization driven covalently-bondedoctahedral-twinning and backbone-peripheral-helical nanoarchitectures, Nano Letters 8(2008) 2258


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