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中国科学院力学研究所导师教师师资介绍简介-武晓雷

本站小编 Free考研考试/2020-05-23

姓名:武晓雷
性别:
职称:研究员
学历:博士
电话:86-
传真:86-
电子邮件:xlwu@imech.ac.cn
通讯地址北京北四环西路15号中国科学院力学研究所

简历:2003.8-现在:研究员,中国科学院力学研究所非线性力学国家重点实验室,先进材料力学行为课题组
2000.11-2003.8:Research Associate, Cleveland State Univ, NASA Joint Laboratory for Materials Research, Ohio, USA
1998.12:副研究员,中国科学院力学研究所,非线性力学国家重点实验室
1996.3-1998.12:博士后,中国科学院力学研究所,材料工艺研究中心
1995.12:博士,西北工业大学,材料科学与工程学院
研究领域:先进材料力学行为及其微结构机理
社会任职:《金属学报》中/英文版 编委
获奖及荣誉:国家自然科学二等奖,“纳米结构金属力学行为尺度效应的微观机理研究”,2013年
国家百千****才工程,并被授予“有突出贡献中青年专家”荣誉称号,2014年
获得政府特殊津贴,2014年
中科院力学研究所中青年科技工作一等奖,2000年

代表论著:发表SCI论文120余篇。
1.Yuan FP, Yan DS, Sun JD, Zhou LL, Zhu YT, Wu XL. Ductility by shear band delocalization in the nano-layer of gradient structure, Materials Research Letters, 7(1), 12-17 (2019)
2.Fu XQ, Wu XL, Yu Q. Dislocation Plasticity Reigns in a Traditional Twinning-Induced Plasticity (TWIP) Steel by in situ Observation, Materials Today Nano, 3, 48-53 (2018)
3.Zhu YT, Wu XL. Ductility and Plasticity of Nanostructured Metals: Differences and Issues, Materials Today Nano, 2, 15-20 (2018)
4.Yang MX, Yan DS, Yuan FP, Jiang P, Ma E, Wu XL. Dynamically reinforced heterogeneous grain structure prolongs ductility in a medium-entropy alloy with gigapascal yield strength, Proceeding of the National Academy of Sciences of the United States of America, 115(28), (2018)
5.He JY, Ma Y, Yan DS, Jiao SH, Yuan FP, Wu XL. Improving ductility by increasing fraction of interfacial zone in low C steel/304 SS laminates, Materials Science and Engineering A, 726, 288-297 (2018)
6.Huang CX, Wang YF, Ma XL, Yin S, Hoppel HW, Goken M, Wu XL, Gao HJ, Zhu YT. Interface affected zone for optimal strength and ductility in heterogeneous laminate, Materials Today (2018)
7.Liu YS, Liu Y, Zhang Q, Zhang CL, Wang J, Wu YX, Han PD, Gao ZP, Wang LP, Wu XL. Control of the microstructure and mechanical properties of electrodeposited graphene/Ni composite, Materials Science and Engineering A, 727, 133-139 (2018)
8.Pan HC, Qin GW, Huang YM, Ren YP, Sha XC, Han XD, Liu ZQ, Li CF, Wu XL, Chen HW, He C, Chai LJ, Wang YZ, Nie JF. Development of low-alloyed and rare-earth-free magnesium alloys having ultra-high strength, Acta Materialia,149, 350-363 (2018)
9.Liu XL, Yuan FP, Zhu YT, Wu XL. Extraordinary Bauschinger effect in gradient structured copper, Scripta Materialia, 150, 57-60 (2018)
10.Ma Y, Yuan FP, Yang MX, Jiang P, Ma E, Wu XL. Dynamic shear deformation of a CrCoNi medium-entropy alloy with heterogeneous grain structures, Acta Materialia, 148, 407-418 (2018)
11.Ma ZW, Ren Y, Li RG, Wang YD, Zhou LL, Wu XL, Wei YJ, Gao HJ. Cryogenic temperature toughening and strengthening due to gradient phase structure, Materials Science and Engineering A, 712, 358-364 (2018)
12.Wang W, Jiang P, Yuan FP, Wu XL. Size effects of nano-spaced basal stacking faults on the strength and deformation mechanisms of nanocrystalline pure hcp metals, Philosophical Magazine, 93(13), 1186-1203 (2018)
13.Wang W, Ma Y, Yang MX, Jiang P, Yuan FP, Wu XL. Strain rate effect on tensile behavior for a high specific strength steel: from quasi-static to intermediate strain rates, Metals, 8(1), 11 (2017)
14.Ma Y, Yang MX, Jiang P, Yuan FP, Wu XL. Plastic deformation mechanisms in a severely deformed Fe-Ni-Al-C alloy with superior tensile properties, Scientific Reports, 7(1), 15619 (2017)
15.Wang W, Yuan FP, Jiang P, Wu XL. Size effects of lamellar twins on the strength and deformation mechanisms of nanocrystalline hcp cobalt, Scientific reports, 7(1), 9550 (2017)
16.Bian XD, Yuan FP, Wu XL, Zhu YT. The evolution of strain gradient and anisotropy in gradient-structured metal, Metallurgical and Materials Transactions A, 48(9), 3951-3960 (2017)
17.Zhang Q, Liu Y, Liu YS, Ren YH, Wu YX, Gao ZG, Wu XL, Han PD. Enhanced tensile ductility and strength of electrodeposited ultrafine-grained nickel with a desired bimodal microstructure, Materials Science and Engineering A,701, 196-202 (2017)
18.Wang W, Yang MX, Yan DS, Jiang P, Yuan FP, Wu XL. Deformation mechanisms for superplastic behaviors in a dual-phase high specific strength steel with ultrafine grains, Materials Science and Engineering A, 702, 133-141 (2017)
19.Wu XL, Zhu YT. Heterogeneous materials: a new class of materials with unprecedented mechanical properties, Materials Research Letters, 5(8), 527-532 (2017)
20.Bian XD, Yuan FP, Zhu YT, Wu XL. Gradient structure produces superior dynamic shear properties, Materials Research Letters, 5(7), 501-507 (2017)
21.Chen L, Yuan FP, Jiang P, Xie JJ, Wu XL. Mechanical properties and deformation mechanism of Mg-Al-Zn alloy with gradient microstructure in grain size and orientation, Materials Science and Engineering A, 694, 98-109 (2017)
22.Wang W, Zhang HS, Yang MX, Jing P, Yuan FP, Wu XL. Shock and spall behaviors of a high specific strength steel: Effects of impact stress and microstructure, Journal of Applied Physics, 121(13), 135901 (2017)
23.Bian XD, Yuan FP, Wu XL. Correlation between strain rate sensitivity and characteristics of Portevin-LeChátelier bands in a twinning-induced plasticity steel, Materials Science and Engineering A, 696, 220-227 (2017)
24.Li JJ, Weng GJ, Chen SH, Wu XL. On strain hardening mechanism in gradient nanostructures, International Journal of Plasticity, 88, 89-107 (2017)
25.Xing JX, Yuan FP, Wu XL. Enhanced quasi-static and dynamic shear properties by heterogeneous gradient and lamella structures in 301 stainless steels, Materials Science and Engineering A, 680, 305-316 (2017)
26.Wu XL, Yang MX, Yuan FP, Chen L, Zhu YT. Combining gradient structure and TRIP effect to produce austenite stainless steel with high strength and ductility, Acta Materialia, 112, 337-346 (2016)
27.Yang MX, Yuan FP, Xie QG, Wang YD, Ma E, Wu XL. Strain hardening in Fe–16Mn–10Al–0.86C–5Ni high specific strength steel, Acta Materialia, 109, 213-222 (2016)
28.Li YP, Han C, Zhang CL, Jia K, Han PD, Wu XL. Effects of alloying on the behavior of B and S at Σ5 (210) grain boundary in γ-Fe, Computational Materials Science, 115, 170-176 (2016)
29.Yang MX, Pan Y, Yuan FP, Zhu YT, Wu XL. Back stress strengthening and strain hardening in gradient structure, Materials Research Letters, 4(3), 145-151 (2016)
30.Yuan FP, Chen P, Feng YP, Jing P, Wu XL. Strain hardening behaviors and strain rate sensitivity of gradient-grained Fe under compression over a wide range of strain rates, Mechanics of Materials, 95, 71-82 (2016)
31.Wu XL, Yang MX, Yuan FP, Wu GL, Wei YJ, Huang XX, Zhu YT. Heterogeneous lamella structure unites ultrafine-grain strength with coarse-grain ductility, Proceeding of the National Academy of Sciences of the United States of America, 112(47), 14501-14505 (2015)
32.Wu XL, Yuan FP, Yang MX, Jiang P, Zhang CX, Chen L, Wei YG, Ma E. Nanodomained nickel unite nanocrystal strength with coarse-grain ductility, Scientific Reports, 5, 11728 (2015)
33.Yuan FP, Wu XL. Size effect and boundary type on the strengthening of nanoscale domains in pure nickel, Materials Science and Engineering A, 648, 243-251 (2015)
34.Wang W, Yuan FP, Wu XL. Smaller critical size and enhanced strength by nano-laminated structure in nickel, Computational Materials Science, 110, 83-90 (2015)
35.Ma XL, Huang CX, Xu WZ, Zhou H, Wu XL, Zhu YT. Strain hardening and ductility in a coarse-grain/nanostructure laminate material, Scripta Materialia, 103, 57-60 (2015)
36.Yuan FP, Wu XL. Size effect and atomistic deformation mechanisms of hierarchically nanotwinned fcc metals under nanoindentation, Journal of Materials Science, 50, 7557-7567 (2015)
37.Han C, Zhang CL, Liu XL, Huang H, Zhuang SY, Han PD, Wu XL. Effects of alloying on oxidation and dissolution corrosion of the surface of γ-Fe (111): a DFT study. Journal of molecular modeling, 21(7), 181 (2015)
38.Yuan FP, Bian XD, Jiang P, Yang MX, Wu XL. Dynamic shear response and evolution mechanisms of adiabatic shear band in an ultrafine-grained austenite-ferrite duplex steel, Mechanics of Materials, 89, 47-58 (2015)
39.Li WB, Yuan FP, Wu XL. Atomistic tensile deformation mechanisms of Fe with gradient nano-grained structure, AIP Advances, 5, 087120 (2015)
40.Wu XL, Jiang P, Chen L, Yuan FP, Zhu YT. Extraordinary strain hardening by gradient structure, Proceedings of the National Academy of Sciences of the United States of America, 111(20), 7197-7201 (2014)
41.Wu XL, Jiang P, Chen L, Zhang JF, Yuan FP, Zhu YT. Synergetic strengthening by gradient structure, Materials Research Letters, 2(4), 185-191 (2014)
42.Yang XS, Sun S, Wu XL, Ma E, Zhang TY. Dissecting the Mechanism of Martensitic Transformation via Atomic-Scale Observations, Scientific Reports, 4,6141 (2014)
43.Li JJ, Wu XL, Soh AK. On nanograin rotation by dislocation climb in nanocrystalline materials, Scripta Materialia, 78-79, 5-8 (2014)
44.Li JJ, Chen SH, Wu XL, Soh AK. Strong crack blunting by shear-coupled migration of grain boundaries in nanocrystalline materials, Scripta Materialia, 84-85, 51-54 (2014)
45.Li JJ, Chen SH, Wu XL, Soh AK. A physical model revealing strong strain hardening in nano-grained metals induced by grain size gradient structure, Materials science and engineering A, 620, 16-21 (2014)
46.Yuan FP, Wu XL. Scaling laws and deformation mechanisms of nanoporous copper under adiabatic uniaxial strain compression, AIP Advances 4,127109 (2014)
47.Chen L, Yuan FP, Jiang P, Xie JJ, Wu XL. Simultaneous improvement of tensile strength and ductility in micro-duplex structure consisting of austentite and ferrite, Materials Science and Engineering A, 618, 563-571 (2014)
48.Yuan FP, Chen P, Wu XL. Tensile deformation mechanisms of the hierarchical structure consisting of both twin-free grains and nanotwinned grains, Philosophical Magazine Letters,94(8), 514-521 (2014)
49.Li JJ, Soh AK, Wu XL. Enhancing dislocation emission in nanocrystalline materials through shear-coupled migration of grain boundaries, Materials Science and Engineering A, 601, 153-158 (2014)
50.Yuan FP, Chen L, Jiang P, Wu XL. Twin boundary spacing effects on shock response and spall behaviors of hierarchically nanotwinned fcc metals, Journal of Applied Physics, 115, 063509 (2014)
51.Dong N, Zhang CL, Liu H, Li J, Wu XL, Han PD. Stress effects on stability and diffusion behavior of sulfur impurity in nickel: A first-principles study, Computational Materials Science, 90, 137-142 (2014).
52.Yuan FP, Wu XL. Hydrostatic pressure effects on deformation mechanisms of nanocrystalline fcc metals, Computational Materials Science, 85, 8-15 (2014)
53.Yuan FP, Wu XL. Atomistic scale fracture behaviors in hierarchically nanotwinned metals, Philosophical Magazine, 93, 3248-3259 (2013)
54.Yuan FP, Wu XL. Formation sequences and roles of multiple deformation twins during the plastic deformation in nanocrystalline fcc metals, Materials Science and Engineering A, 580, 58-65 (2013)
55.Yuan FP, Wu XL. Size effects of primary/secondary twins on the atomistic deformation mechanisms in hierarchically nanotwinned metals, Journal of Applied Physics, 113, 203516 (2013)
56.Zhu YT, Liao XZ, Wu XL, Narayan J. Grain size effect on deformation twinning and detwinning, Journal of Materials Science, 48(13), 4467-4475. (2013)
57.Zhu YT, Liao XZ, Wu XL. Deformation twinning in nanocrystalline materials, Progress in Materials Science, 57, 1-62 (2012)
58.Chen L, Yuan FP, Jiang P, Wu XL. Mechanical properties and nanostructures in a duplex stainless steel subjected to equal channel angular pressing, Materials Science and Engineering A, 551, 154-159 (2012)
59.Yuan FP, Jiang P, Wu XL. Annealing effect on the evolution of adiabatic shear band under dynamic shear loading in ultra-fine-grained iron, International Journal of Impact Engineering, 50, 1-8 (2012)
60.Yuan FP, Wu XL. Layer thickness dependent tensile deformation mechanisms in sub-10 nm multilayer nanowires, Journal of Applied Physics, 111(12), 124313 (2012)
61.Zhang XY, Li B, Wu XL, Zhu YT, Ma Q, Liu Q, Wang PT, Horstemeyer MF. Twin boundaries showing very large deviations from the twinning plane, Scripta Materialia, 67(10), 862-865. (2012)
62.Yuan FP, Wu XL. Shock response of nanotwinned copper from large-scale molecular dynamics simulations, Physical Review B, 86(13), 134108 (2012)
63.Yuan FP, Jiang P, Xie JJ, Wu XL. Analysis of spherical indentation of materials with plastically graded surface layer, International Journal of Solids and Structures, 49(3-4), 527-536 (2012)
64.Wei QM, PanZL, Wu XL, Schuster BE, Kecskes LJ, Valiev RZ. Microstructure and mechanical properties at different length scales and strain rates of nanocrystalline tantalum produced by high-pressure torsion, Acta Materialia, 59(6), 2423-2436(2011)
65.Wu XL, Youssef KM, Koch CC, Mathaudhu SN, Kecskes LJ, Zhu YT. Deformation twinning in a nanocrystalline hcp Mg alloy, Scripta Materialia, 64(3), 213-216 (2011)
66.Xu WC, Dai PQ, Wu XL, Tang D. Study on nanocrystalline dual phase Ni-Co alloy with high strength and excellent ductility, Materials Science and Technology, 27(1), 320-324(2011)
67.Zhu YT, Wu XL, Liao XZ, Narayan J, Kecskes LJ, Mathaudhu SN. Dislocation-twin interactions in nanocrystalline fcc metals, Acta Materialia, 59(2), 812-821(2011)
68.Li JJ, Chen SH, Wu XL, Soh A, Lu J. The main factor influencing the tensile properties of surface nano-crystallized graded materials, Materials Science and Engineering A, 527(26), 7040-7044(2010)
69.Xu WC, Dai PQ, Wu XL. Effect of stress-induced grain growth during room temperature tensile deformation on ductility in nanocrystalline metals, Bulletin of Materials Science, 33(5), 561-568 (2010)
70.Xie ZL, Xie JJ, Hong YS, Wu XL. Influence of processing temperature on microstructure and microhardness of copper subjected to high-pressure torsion, Science China Technological Sciences, 53(6), 1534-1539 (2010)
71.Wu XL, Zhu YT, Wei YG, Wei Q. Strong Strain Hardening in Nanocrystalline Nickel, Physical Review Letters, 103, 205504 (2009)
72.Zhu YT, Wu XL, Liao ZX, Narayan J, Mathaudhu SN, and Kecskés LJ. Twinning partial multiplication at grain boundary in nanocrystalline fcc metals, Applied Physics Letters, 95, 031909 (2009)
73.Zhu YT, Narayan J, Hirth JP, Mahajan S, Wu XL, Liao XZ. Formation of Single and Multiple Deformation Twins in Nanocrystalline fcc Metals, Acta Materialia, 57, 3763 (2009)
74.Wu XL, Guo YZ, Wei Q, Wang WH. Prevalence of Shear Banding in Compression of Zr41Ti14Cu12.5Ni10Be22.5 Pillars as Small as 150 nm in Diameter, Acta Materialia, 57, 3562 (2009)
75.Zhang XY, Wu XL, Zhu AW. Growth of deformation twins in room-temperature rolled nanocrystalline nickel, Applied Physics Letters, 94, 121907 (2009)
76.Wu XL. Plastic deformation of nanocrystalline nickel, Science in China Series E 52 (8), 2216-2221 (2009)
77.Li PY, Cao ZH, Zhang XY, Wu XL, Huang YN, Meng XK. Curie transition of NC nickel by mechanical spectroscopy and magnetization study, Chinese Physics Letters 26, 036102 (2009 )
78.Wu XL, Zhu YT. Inverse grain-size effect on twinning in nanocrystalline Ni, Physical Review Letters 101, 025503 (2008)
79.Wu XL, Liao XZ, Srinivasan SG, Zhou F, Lavernia EJ, Valiev RZ, Zhu YT. New deformation twinning mechanism generates zero macroscopic strain in nanocrystalline metals, Physical Review Letters 100, 095701 (2008)
80.Wu XL, Narayan J, Zhu YT. Deformation twin formed by self-thickening, cross-slip mechanism in nanocrystalline Ni, Applied Physics Letters, 93, 031910 (2008)
81.Zhang XY, Wu XL, Liu Q, Zuo RL, Zhu AW, Jiang P, Wei QM. Phase transformation accommodated plasticity in nanocrystalline nickel, Applied Physics Letters, 93, 031901 (2008)
82.Zhu YT, Liao XZ, Wu XL. Deformation twinning in bulk nanocrystalline metals: Experimental observations, JOM. 60, 60-64 (2008)
83.Zhang XY, Liu Q, Wu XL, Zhu AW. Work softening and annealing hardening of deformed nanocrystalline nickel, Applied Physics Letters, 93, 261907 (2008)
84.Wu XL, Ma E. Dislocations and twins in nanocrystalline Ni after severe plastic deformation: the effects of grain size, 14th International Conference on the Strength of Materials (ICSMA 14). Materials Science and Engineering A, 483, 84-86 (2008)
85.Li PY, Zhang XY, Wu XL, Huang YN, Meng XK. Internal friction of bend-deformed nanocrystalline nickel by mechanical spectroscopy, Chinese Physics Letters, 25, 4339-4341 (2008)
86.Xie JJ, Wu XL, Hong YS. Study on fatigue crack nucleation of electrode posited nanocrystalline nickel, 7th International Conference on Fracture and Strength of Solids. Advances in Fracture and Materials Behavior, 33-37, 925-930 (2008)
87.Wang ZJ, Wu XL, Hong YS. Torsion fracture behavior of drawn pearlitic steel wires with different heat treatments, 7th International Conference on Fracture and Strength of Solids. Advances in Fracture and Materials Behavior 33-37, 41-46 (2008)
88.Wu XL, Tao NR, Wei QM, Jiang P, Lu J, Lu K. Microstructural evolution and formation of nanocrystalline intermetallic compound during surface mechanical attrition treatment of cobalt, Acta Materialia, 55, 5768-5779 (2007)
89.Wu XL, Li B, Ma E. Vacancy clusters in ultrafine grained Al by severe plastic deformation, Applied Physics Letters, 91, 141908 (2007)
90.Wu XL, Qi Y, Zhu YT. Partial-mediated slips in nanocrystalline Ni at high strain rate, Applied Physics Letters, 90, 221911 (2007)
91.Wu XL, Ma E. Accommodation of large plastic strains and defect accumulation in nanocrystalline Ni grains, Journal of Materials Research, 22, 2241-2253 (2007)
92.Jiang P, Wei QM, Hong YS, Lu J, Wu XL. In situ synthesis of nanocrystalline intermetallic layer during surface plastic deformation of zirconium, Surface & Coating Technology, 202, 583-589 (2007)
93.Xie JJ, Wu XL, Hong YS. Shear bands at the fatigue crack tip of nanocrystalline nickel, Scripta Materialia, 57, 5-8 (2007)
94.Wu XL, Ma E, Zhu YT. Deformation defects in nanocrystalline nickel, Nanomaterisls-Materials and Processing for Functional Applications held at the 2006 TMS Spring Meeting. Journal of Materials Science, 42, 1427-1432 (2007)
95.Ma E, Shen TD, Wu XL. Nanostructured metals: Less is more, Nature Materials, 5, 515-516 (2006)
96.Wu XL, Zhu YT. Partial-dislocation-mediated processes in nanocrystalline Ni with nonequilibrium grain boundaries, Applied Physics Letters 89, 031922 (2006)
97.Wu XL, Ma E. Dislocations in nanocrystalline grains, Applied Physics Letters, 88, 231911 (2006)
98.Wu XL, Zhu YT, Ma E. Predictions for partial-dislocation-mediated processes in nanocrystalline Ni by generalized planar fault energy curves: An experimental evaluation, Applied Physics Letters, 88, 121905 (2006)
99.Wu XL, Ma E. Deformation twinning mechanisms in nanocrystalline Ni, Applied Physics Letters 88, 061905 (2006)
100.Wu XL, Zhu YT, Chen MW, Ma E. Twinning and stacking fault formation during tensile deformation of nanocrystalline Ni, Scripta Materialia, 54, 1685-1690 (2006)
101.Wu XL, Tao NR, Hong YS, Liu G, Xu B, Lu J, Lu K. Strain-induced grain refinement of cobalt during surface mechanical attrition treatment, Acta Materialia, 53, 681-691 (2005)
102.Wu XL, Tao NR, Hong YS, Lu J, Lu K. gamma→ epsilon martensite transformation and twinning deformation in fcc cobalt during surface mechanical attrition treatment, Scripta Materialia, 52, 547-551 (2005)
103.Wu XL, Tao NR, Hong YS, Lu J, Lu K. Localized solid-state amorphization at grain boundaries in a nanocrystalline Al solid solution subjected to surface mechanical attrition, Journal of Physics D-Applied Physics, 38, 4140-4143 (2005)
104.Zhang XY, Wu XL, Xia BY, Zhou MZ, Zhou SJ, Jia C. Step structure in cold-rolled deformed nanocrystalline nickel, Chinese Physics Letters, 22, 2335-2337 (2005)
105.Zhang XY, Hu ZL, Wu XL, Xia BY, Zhou MZ, Zhou SJ, Jia C. A study on the microstructure characteristic of the cold-rolled deformed nanocrystalline nickel, Reviews on Advanced Materials Science, 10, 181-184 (2005)
106.Tao NR, Wu XL, Sui ML, Lu J, Lu K. Grain refinement at the nanoscale via mechanical twinning and dislocation interaction in a nickel-based alloy, Journal of Materials Research, 19, 1623-1629 (2004)
107.Wei YG, Zhu C, Wu XL. Micro-scale mechanics of the surface-nanocrystalline Al-alloy material, Science in China Series G-Physics Astronomy 47, 86-100 (2004)
108.Wu XL, Tao NR, Hong YS, Xu B, Lu J, Lu K. Microstructure and evolution of mechanically-induced ultrafine grain in surface layer of AL-alloy subjected to USSP, Acta Materialia, 50, 2075-2084 (2002)
109.Wu XL, Xu B, Hong YS. Synthesis of thick Ni66Cr5Mo4Zr6P15B4 amorphous alloy coating and large glass-forming ability by laser cladding, Materials Letters, 56, 838-841 (2002)
110.Wu XL, Hong YS. Fe-based thick amorphous-alloy coating by laser cladding, Surface and Coatings Technology,141(2-3), 141-144 (2001)
111.Wu XL, Hong YS. Microstructure and mechanical properties at TiCp/Ni-alloy interfaces in laser-synthesized coatings, Materials Science and Engineering A, 318(1-2), 15-21 (2001)
112.Wu XL, Hong YS. Novel Fe70Zr10Ni6Al4Si6B4 thick metallic glass coating produced by laser cladding, Materials science and technology, 17(8), 1025-1028 (2001)
113.Wu XL, Hong YS. Surface amorphous and crystalline microstructure by alloying zirconium using Nd: YAG pulsed laser, Metallurgical and Materials Transactions A-Physical Metallurgy and Materials Science, 31, 3123-3127 (2000)
114.Wu XL, Hong YS. Microstructural evolution of a laser-cladded coating, Scripta Materialia, 43, 123-127 (2000)
115.Wu XL, Hong YS. Microstructure of Zr-alloyed coating using pulsed laser, Surface and Coatings Technology, 132(2-3), 194-197 (2000)
116.Wu XL, Chen GN. Nonequilibrium microstructures and their evolution in a Fe–Cr–W–Ni–C laser clad coating, Materials Science and Engineering A, 270(2), 183-189 (1999)
117.Wu XL. Rapidly solidified nonequilibrium microstructure and phase transformation of laser-synthesized iron-based alloy coating, Surface and Coatings Technology, 115(2-3), 153-162 (1999)
118.Wu XL, Chen GN. Microstructural features of an iron-based laser coating, Journal of materials science, 34(14), 3355-3361 (1999)
119.Wu XL. Thermodynamics of the Displacive Mechanism of α1 Transformation in a β′ Copper-Zinc Alloy, Materials Transactions, JIM, 40(10), 1098-1101 (1999)
120.Wu XL, Chen GN. Microstructural characteristics and carbide transformation of laser-cladded Fe-Cr-W-Ni-C coatings during high-temperature tempering, Journal of materials science letters, 17(21), 1849-1852 (1998)
121.Xie ZY, Kang MK, Wu XL. A regular thermodynamic model for interstitial iron-carbon solutions, Acta metallurgica et materialia, 42(6), 1825-1828 (1994)

承担科研项目情况:新型纳米金属材料的塑性变形机制及结构性能关系研究,科技部国家重大研发项目 (No.2017YFA**)2017.7-2022.6
中熵合金氮固溶与跨尺度异构的强韧化及其微观研究, 国家自然科学基金 (No.**)2020.1-2023.12
先进材料力学行为与微结构关联研究,B类先导专项 (No.XDB**)2017.7-2022.6
梯度层片纳米晶结构的均匀拉伸塑性与应变硬化机理研究,国家自然科学基金(负责人,No.**)2016.1-2019.12
梯度纳米结构表层材料的微观塑性行为,国家自然科学基金 (负责人,No.**),2011.1-2013.12
多级纳米结构的稳定性研究及部分多级纳米金属材料的工业应用探索,国家重大科学研究计划研究项目(学术骨干,No.2012CB932203),2012.1-2016.08
纳米材料及结构力学行为的表征理论和参量确定,国家重大科学研究计划研究项目(学术骨干,No.2012CB937500),2012.1-2016.08
六方结构纳米金属的塑性变形机制,国家自然科学基金 (负责人,No.**),2005.1-2007.12
亚稳态超细/纳米晶粒组织的塑性变形机制与力学性能,国家自然科学基金 (负责人,No. **),2006.1-2008.12
材料介观尺度效应的结构特征,国家重大基础研究项目(学术骨干,No.2010CB631004 ),2005.1-2009.12
中国科学院知识创新工程重大项目 (子课题负责人) 2007-2010
国家安全重大基础问题研究项目 (子课题负责人,No. **),2009-2015
纳米晶金属的塑性行为及其微结构机理,国家自然科学基金 (负责人,No.**)2010-2012

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