张林杰

职 称:

所在系所:

个人主页:http://gr.xjtu.edu.cn/web/zhanglinjie

E-MAIL:zhanglinjie@mail.xjtu.edu.cn

专业方向:激光焊接、增材制造

一、研究领域

难熔金属与新能源材料的激光焊接及增材制造

二、工作经历

2020.01 - 至今     西安交通大学bwin必赢        教授

2015.01 - 2019.12   西安交通大学bwin必赢        副教授

2008.07 - 2014.12   西安交通大学bwin必赢        讲师

三、教育经历

2003.03 - 2008.03 西安交通大学   材料加工工程专业    博士

2000.09 - 2003.03 西北工业大学   材料加工工程专业    硕士

1991.09 - 1995.07 哈尔滨工业大学 焊接工艺及设备专业  学士

四、学术成果

目前发表SCI论文100余篇,Web of Science引用1600余次。获批软件著作权7项,授权国家发明专利20余项。主持国家自然科学基金2项、国家重点研发计划项目子课题1项、省部级基金4项、横向课题20余项。作为主要参加人参加过国家863计划、科技支撑计划及多项国家自然科学基金。获陕西高等学校科学技术奖一等奖2项。

五、获批软著

[7] 2022SR0838333,激光填丝焊接过程金属流动传热行为计算软件V1.0.

[6] 2022SR1293749,基于路况载荷的焊接结构疲劳寿命及多级疲劳载荷谱计算软件V1.0.

[5] 2021SR1212096,基于光路追踪的激光焊接气液界面传热计算软件V1.0.

[4] 2021SR1212098,激光焊接气液界面运动驱动力计算软件V1.0.

[3] 2021SR1212091,基于光路追踪的激光电弧复合焊气液界面传热传质计算软件V1.0.

[2] 2021SR1234926,激光电弧复合焊气液界面运动驱动力计算软件V1.0.

[1] 2021SR1212097,基于渐进式光路追踪的铺粉3D打印气液界面传热传质计算软件V1.0.

六、授权专利

[24] ZL 202111514324.3,一种大厚板窄间隙激光填丝焊成形质量的控制方法.

[23] ZL 202111007767.3, 一种原位生成氮化铝增强铝基复合材料及其制备方法.

[22] ZL 202110112214.8, 一种铁基材料载能束粉末增材修复的集约化方法.

[21] ZL202110595308.5,促进钛合金增材制造柱状晶向等轴晶转变和组织细化方法.

[20] ZL20210707153337,一种增材修复用钛焊丝及其制备方法.

[19] ZL2020102729327,一种钼合金事故容错燃料棒的焊接封装方法.

[18] ZL2020104277150, 一种基于激光扫描的窄间隙厚板填丝焊接方法.

[17] ZL201910872920.5,电弧增材制造应急修复船舶受损Al-Mg系铝合金构件的方法.

[16] ZL201911329190.0,一种微米级RE2O3多级细化组织的钛合金填丝增材制造方法.

[15] ZL201911288776.7,一种含工艺台阶外部件与薄板基体的激光调制焊接方法.

[14] ZL2019109953513,基于超声波驻场防止熔池下榻的发卡式接头焊缝控形系统.

[13] ZL2017109097222,一种基于热循环调控的钼及钼合金激光焊接方法.

[12] ZL2019103421679,一种钼滤网叠层结构的孔眼嵌填钛粉电阻焊方法.

[11] ZL2019107118863,一种研究钼合金高压环境激光焊接的无增压泵焊接实验装置.

[10] ZL2018116167154,一种厚板单面填充焊接接头残余应力变形控制方法.

[9] ZL2017102842510,一种基于微合金化与同步寄生钎焊的钼合金熔焊方法.

[8] ZL2017102834552, 一种提高钼及钼合金熔焊焊缝强韧性的微合金化方法.

[7] ZL2018102366241,一种核燃料棒包壳高压充氦与激光焊接成套焊接设备.

[6] ZL2017101340610,一种用于大长径比燃料棒包壳环焊的激光焊接装置.

[5] ZL2017108126340,基于波形调制的钼及钼合金对接接头的脉冲激光焊接方法.

[4] ZL2017104333271,提高机械结合型双金属复合管中覆层与基层结合强度的方法.

[3] ZL2016106171718,以T2紫铜作为过渡层的钛 钢复合板激光填丝对接焊方法.

[2] ZL2016108751826,一种基于阶梯孔法的内部残余应力测量方法.

[1] ZL2014102137827,厚钢板激光全穿透焊接熔池三维形状检测及重构方法.

七、学术论文

[121] Han Yu, Hongda Zhang*, Linjie Zhang*, et al. Regulation of performance of laser-welded socket joint of Mo-14Re ultra- high-temperature heat pipe by introducing Ti into both weld and heat affected zone[J]. Journal of Materials Research and echnology, 2022.

[120] Feipeng An, Linjie Zhang, Jie Ning et al.Influence of annealing on the microstructure and Charpy impact toughness of wire arc additive manufactured Ti5111 alloy[J]. Materials Science and Engineering A, 2022, 860: 144255..

[119] Long J., Zhang LJ., Ning J. et al. Effect of ambient pressure change on pure tungsten laser spot welding [J]. Welding in the World, 2022, 66: 2403.

[118] Jie Ning, Zheng-Xiong Ma, Lin-Jie Zhang, Di-Pin Wang, Suck-Joo Na. Effects of magnesium on microstructure, properties and degradation behaviors of zinc-based alloys prepared by selective laser melting [J]. Materials Research Express, 2022, 9(8): 086511.

[117] Jian Long, Jin-Long Jia, Lin-Jie Zhang, Ming-Xiang Zhuang, Jiu-Hui Wu, Fatigue inhomogeneity of 140 mm thick TC4 titanium alloy double-sided electron beam welded joints [J]. International Journal of Fatigue, 2022, 165: 107214.

[116] Mirza Zahid Hussain, Jiangtao Xiong, Jinglong Li, Farah Siddique, Lin Jie Zhang et al. Structural characterization of a composite joint prepared during laser welding of Ti–22Al–27Nb intermetallic alloy with an interlayer of Cu-Hf-Ni-Ti-Zr high entropy bulk metallic glass [J]. Composites Part B: Engineering, 2022, 243: 110167.

[115] Jian Long, Jie Ning, Linjie Zhang, Suck-Joo Na. Fiber laser spot welding of Mg–10Li–3Al–3Zn alloy in a hyperbaric environment [J]. Applied Physics B, 2022, 128: 114.

[114] Liang Liang Zhang, Linjie Zhang, Qing-Jie Yang. Weldability of Molybdenum–Rhenium Alloy Based on a Single-Mode Fiber Laser [J]. Metals, 2022, 12(5), 841.

[113] Jie Ning, Jia-Hao Wen, Lin-Jie Zhang, Suck-Joo Na, Assessment of the universality of duplex stainless steel powder in laser additive repair based on Schaeffler diagram [J]. Additive Manufacturing, 2022, 55: 102864.

[112] Han Yu, Long-Zheng Pan, Linjie Zhang et al. Effect of Beam Oscillating and Nitrogen Alloying Upon Microstructure and Mechanical Properties in Laser Welding of Molybdenum Alloy [J]. Transactions of the China Welding Institution, 2022 43(5): 49-55.

[111] Cheng, PX., Zhang, LJ., Ning, J. et al. Effects of Addition of Titanium on Microstructures and Properties of Laser Butt Welded Joints of Mo–30W Alloy [J]. J. of Materi Eng and Perform,2022 https://doi.org/10.1007/s11665-022-06863-9.

[110] Xiang Wang, Lin-Jie Zhang, Jie Ning, Suck-joo Na, Fluid thermodynamic simulation of Ti-6Al-4V alloy in laser wire deposition [J]. 3D Printing and Additive Manufacturing, 2022. doi.org/10.1089/3dp.2021.0159.

[109 Mirza Zahid Hussain, Xiong Jiangtao, Li Jinglong, Farah Siddique, Lin Jie Zhang, Xian Rong Zhou [J]. Effect of Ta microalloying on joint performance by tailoring the microstructure during laser beam welding of Ti-22Al-27Nb, Materials Science and Engineering: A, 2022, 845: 143157.

[108] Jian Long, Lin-Jie Zhang, Ming-Xiang Zhuang, Li-an Bai, Suck-Joo Na, Narrow-gap laser welding with beam wobbling and filler wire and microstructural performance of joints of thick TC4 titanium alloy plates [J]. Optics & Laser Technology, 2022, 152: 108089.

[107] Mirza Zahid Hussain, Jiangtao Xiong, Jinglong Li, Farah Siddique, Lin Jie Zhang, Yajie Du, Xian Rong Zhou, Effect of Ti-Hf-Zr-Cu-Ni high entropy alloy addition on laser beam welded joint of Ti2AlNb based intermetallic alloy [J]. Journal of Materials Science & Technology, 2022, 120: 214-226.

[106] Long, J, Zhang, L-J, Zhang, L-X, Wu, J, Zhuang, M-X. Comparison of fatigue performance of TC4 titanium alloy welded by electron beam welding and laser welding with filler wire [J]. Fatigue Fract Eng Mater Struct. 2022; 45( 4): 991- 1004.

[105] Jie Ning, Hai-Bo Zhang, Su-Ming Chen, Lin-Jie Zhang, Suck Joo Na, Intensive laser repair through additive manufacturing of high-strength martensitic stainless steel powders (II): evaluation of intensive repair ability of high strength martensitic steel powder based on Schaeffler diagram [J]. Journal of Materials Research and Technology, 2022, 16: 1494-1507.

[104] Pubo Li, Luyao Chen, Bintao Wu, Linjie Zhang, Mangmang Gao, Strength-ductility synergy of reduced graphene oxide/2024Al matrix composites by heterogeneous structure design and hybrid nanoparticles optimized interface [J]. Journal of Alloys and Compounds, 2022, 898: 162757.

[103] Xiang Wang, Linjie Zhang*, Jie Ning, et al. Fe element promotes the transformation from columnar to equiaxed grains and the formation of ultrafine microstructure of Ti-6Al-4V alloy by laser wire deposition[J]. Additive Manufacturing, 2021, 48: 102442.

[102] Sang-Woo Han, Won-Ik Cho, Linjie Zhang, Suck-Joo Na*. Coupled Simulation of Thermal-Metallurgical-Mechanical Behavior in Laser Keyhole Welding of AH36 Steel [J]. Materials & Design, 2021, 212: 110275.

[101] Xiang Wang, Linjie Zhang*, Jie Ning, Suck-Joo Na. Effect of Cu-induced eutectoid transformation on microstructure and mechanical properties of Ti–6Al–4V alloy by laser wire deposition [J]. Materials Science and Engineering A, 2021, 142316.

[100] Zheng-Xiong Ma, Jie Ning, Bing Yu, Linjie Zhang*, et al. Effects of process parameters and scanning patterns on quality of thin-walled copper flanges manufactured by selective laser melting [J]. Journal of Manufacturing Processes, 2021, 72: 419-430.

[99] Zheng-Xiong Ma, Pei-Xin Cheng, Jie Ning, Lin-Jie Zhang and Suck-Joo Na. Innovations in Monitoring, Control and Design of Laser and Laser-Arc Hybrid Welding Processes [J]. Metals, 2021, 11: 1910.

[98] Jie Ning, Hai-Bo Zhang, Su-Ming Chen, Linjie Zhang*, et al. Intensive laser repair through additive manufacturing of high-strength martensitic stainless steel powders (I) –powder preparation, laser cladding and microstructures and properties of laser-cladded metals[J]. Journal of Materials Research and Technology, 2021, 15: 5746-5761.

[97] Sen Li, Linjie Zhang*, Jie Ning, et al. Microstructures and properties of wire-arc additively manufactured 5356 aluminium alloy protected by different proportions of nitrogen and argon [J]. Journal of Materials Science, 2021, 56: 17785-17804.

[96] Zhuang MX, Liu YQ, Liu B, Wang WX, Long J., Zhang LJ*. Microstructure and Properties of Double-side and Double-pass Unequal Penetration EBW TC4 Joint in Hollowed-out Load-bearing Thick Beam [J]. Rare Metal Materials and Engineering, 2021, 50(8): 2933-2940.

[95] Liang-Liang Zhang, Lin-Jie Zhang*, Jie Ning, et al. Effect of various combinations of Ti and Zr interlayers on the tensile properties of laser welded joints of molybdenum [J]. International Journal of Refractory Metals and Hard Materials, 2021, 101:105662.

[94] Liang-Liang Zhang, Lin-Jie Zhang*, Jie Ning, et al. On the laser gas (N2) alloying in the welding of molybdenum alloy [J]. Journal of Materials Processing Technology, 2021, 296(1): 117184.

[93] Wei Ma, Jie Ning, Lin-Jie Zhang, Suck-Joo Na. Regulation of microstructures and properties of molybdenum silicon boron alloy subjected to selective laser melting [J]. Journal of Manufacturing Processes, 2021,69: 593-601.

[92] Xian-Rong Zhou, Jie Ning, Suck-Joo Na, Lin-Jie Zhang. Microstructures and properties of the dissimilar joint of pure molybdenum/T2 copper by single-mode laser welding [J]. International Journal of Refractory Metals and Hard Materials, 2021, 101: 105667.

[91] Liang-Liang Zhang, Lin-Jie Zhang*, Jie Ning, et al. Strengthening mechanisms of combined alloying with carbon and titanium on laser beam welded joints of molybdenum alloy [J]. Journal of Manufacturing Processes, 2021, 68(3):1637-1649.

[90] Xiang Wang, Lin-Jie Zhang*, Jie Ning, et al. Hierarchical grain refinement during the laser additive manufacturing of Ti-6Al-4V alloys by the addition of micron-sized refractory particles [J]. Additive Manufacturing, 2021, 45: 102045.

[89] Jian Long, Lin-Jie Zhang*, Jie Ning, et al. Zoning study on the fatigue crack propagation behaviors of a double-sided electron beam welded joint of TC4 titanium alloy with the thickness of 140mm [J]. International Journal of Fatigue, 2021, 146: 106145.

[88] Jian Long, Lin-Jie Zhang*, Jie Ning, et al. Effects of post-weld heat treatment on microstructures and properties of laser welded joints of new high-strength Ti-55531 alloy [J]. Journal of Manufacturing Processes, 2021, 64:1329-1335.

[87] Sang-Woo Han, Cho Won-Ik , Lin-Jie Zhang , Suck-Joo Na, et al. A study on laser keyhole welding in vacuum by computational fluid dynamics simulations with plume effect models [J]. Journal of Laser Applications, 2021, 33(1): 12042.

[86] Sen Li, Ning J, Gui-Feng Zhang, Lin-Jie Zhang*, et al. Microstructural and mechanical properties of wire-arc additively manufactured Al–Zn–Mg aluminum alloy: The comparison of as-deposited and heat-treated samples [J]. Vacuum, 2021, 184(6):109860.

[85] Jian Long, Lin-Jie Zhang*, Jie Ning, et al. Dynamic behavior of plasma and molten pool of pure titanium during hyperbaric laser welding [J]. Infrared Physics & Technology, 2021, 115(10):103686.

[84]Jian Long, Lin-Jie Zhang*, Jie Ning, et al. Instantaneous phenomena during the pulsed fiber laser welding of pure zirconium in a hyperbaric environment [J]. Optics Communications, 2021, 490: 126868.

[83] Liang-Liang Zhang, Lin-Jie Zhang*, Jie Ning, et al. On the role of pre-nitriding on improving the weldability of molybdenum alloy [J]. Materials & Design, 2021, 198(3):109377.

[82] Xiang Wang, Lin-Jie Zhang*, Jie Ning, et al. Effect of addition of micron-sized lanthanum oxide particles on morphologies, microstructures and properties of the wire laser additively manufactured Ti–6Al–4V alloy [J]. Materials Science and Engineering A, 2021, 803:140475.

[81] Jian Long, Lin-Jie Zhang*, Jie Ning, et al. Analysis of heterogeneity of fatigue properties of double-sided electron beam welded 140-mm thick TC4 titanium alloy joints [J]. International Journal of Fatigue, 2021, 142: 105942.

[80] Jie Ning, Lin-Jie Zhang*, Bai-Yu Yang, Yuan-Jun Sun, et al. Improved quality of resistance spot welded joints for molybdenum sheets in lap configuration by adding titanium interlayer [J]. Materials Research Express, 2021, 8(6):066522.

[79] Jie Ning, Suck-Joo Na, Lin-Jie Zhang, Chen-Hong Wang. A comparison of laser-metal inert gas hybrid welding and metal inert gas welding of high-nitrogen austenitic stainless steel [J]. Journal of Materials Research and Technology, 2021, 13(2):1841-1854.

[78] Jie Ning, Suck-Joo Na*, Lin-Jie Zhang, et al. Improving thermal efficiency and stability of laser welding process for magnesium alloy by combining power modulation and subatmospheric environment [J]. Journal of Magnesium and Alloys, 2021.

[77] Sen Li, Lin-Jie Zhang, et al.  Microstructures and mechanical properties of Al-Zn-Mg aluminium alloy components produced by wire + arc additive manufacturing  [J],  Journal of Materials Research and Technology, 2020.  (IF=5.29)

[76] Jian Long, Lin-Jie Zhang*, et al. Analysis of heterogeneity of fatigue properties of an ultra-thick joints [J], International Journal of Fatigue, 2020.

[75] Jian Long, Lin-Jie Zhang*, et al. The influence of pressures in a hyperbaric environment on the penetration during pulsed laser welding of 304 stainless steels and underlying mechanism [J], Journal of Laser Applications , 2020.

[74] Lin-Jie Zhang, Hai-Bo Zhang*, et al.  Laser processing of Mg-10Li-3Al-3Zn alloy: Part Ⅰ - Microstructure and properties of laser welded joints [J], Journal of Manufacturing Processes, 2020.

[73] Liang-Liang Zhang, Lin-Jie Zhang*, et al. Improvement in the weldability of molybdenum alloy by pre-welding solid carburising [J], Journal of Materials Science & Technology, 2020. (IF=5.04)

[72] Hai-Bo Zhang, Lin-Jie Zhang*, et al. Microstructures and performances of the butt joint of TA1/Q235B bimetallic sheet with addition of a Mo interlayer by using narrow gap laser welding with filler wire [J],  Journal of Materials Research and Technology, 2020.  (IF=5.29)

[71] Ning J, Zhang LJ*, et al. Effects of power modulation on behaviours of molten pool and keyhole during laser–arc hybrid welding of pure copper [J], Materials & Design, 2020, 194: 108829. (IF=6.289)

[70] Lin-Jie Zhang, Hai-Bo Zhang*, et al. Laser processing of Mg-10Li-3Al-3Zn alloy:Part II- Improving corrosion resistance of multi-phase Mg alloys by laser surface processing [J], Journal of Manufacturing Processes, 2020, 56: 571-580.

[69] Lin-Jie Zhang, Ru-Yuan Ma*, Yan-Bin Zhang, Qian Guo, Chen-Hong Wang, Jian-Xun Zhang, Suck-Joo Na. Investigation on dissimilar laser beam welding of molybdenum to zirconium via pure titanium interlayer [J]. Optics and Laser Technology, 2020, 131: 106327.

[68] Jian Long, Lin-Jie Zhang*, et al. Towards better understanding of hyperbaric fiber laser spot welding of metallic material [J], Journal of Manufacturing Processes, 2020. 56: 372-381.

[67] Jiahao Wen, Lin-Jie Zhang, Jie Ning, et al. Laser additively manufactured intensive dual-phase steels and their microstructures, properties and corrosion resistance [J], Materials & Design, 2020, 169: 107681. (IF=6.289)

[66] Sen Li, Lin-Jie Zhang, Jie Ning, et al. Comparative study on the microstructures and properties of wire+arc additively manufactured 5356 aluminium alloy with argon and nitrogen as the shielding gas [J], Additive Manufacturing, 2020,101206. (IF=7.002)

[65] Lin-Jie Zhang, Qian Guo*, et al. Evolution of microstructures and performance of laser welded GH3128/Mo dissimilar joints [J], Journal of Materials Engineering and Performance, 2020, 29:1792–1809.

[64] Jian Long, Lin-Jie Zhang*, et al. Fiber laser spot welding of molybdenum alloy in a hyperbaric environment[J], Optics Express, 2020, 28(6): 7843-7857.

[63] Jian Long, Lin-Jie Zhang*, Liang-Liang Zhang, Xiang Wang, Gui-Feng Zhang, Jian-Xun Zhang. Effects of minor Zr addition on the microstructure and mechanical properties of laser welded joint of Al/SiCp metal-matrix composite [J], Journal of Manufacturing Processes, 2020, 49: 373–384.

[62] Jian Long, Lin-Jie Zhang*, Qun-Bing Zhang, Wen-Ke Wang, Jie Zhong, Jian-Xun Zhang. Microstructural characteristics and low cycle fatigue properties at 230°C of different weld zone materials from a 100mm thick dissimilar weld of ultra-supercritical rotor steel [J], International Journal of Fatigue, 2020, 130: 105248.

[61] Liang-Liang Zhang, Lin-Jie Zhang*, Jian Long, Jie Ning, Jian-Xun Zhang, Suck-Joo Na. Effects of titanium on grain boundary strength in molybdenum laser weld bead and formation and strengthening mechanisms of brazing layer [J]. Materials & Design, 2019, 169: 107681.

[60] Lin-Jie Zhang, Jiang-Zhe Liu*, Jun-Yu Pei, Jie Ning, Liang-Liang Zhang, Jian Long, Gui-Feng Zhang, Jian-Xun Zhang, Suck-Joo Na. Effects of Power Modulation, Multipass Remelting and Zr Addition Upon Porosity Defects in Laser Seal Welding of End Plug to Thin-Walled Molybdenum Alloy [J]. Journal of Manufacturing Processes, 2019, 41: 197–207.

[59] Liang-Liang Zhang, Lin-Jie Zhang, Jian Long, Xu Sun, Jian-Xun Zhang, Suck-Joo Na. Enhanced mechanical performance of fusion zone in laser beam welding joint of molybdenum alloy due to solid carburizing [J]. Materials and Design, 2019, 181: 107957.

[58] Lin-Jie Zhang, Chen-Hong Wang*, Yan-Bin Zhang, Qian Guo, Ru-Yuan Ma, Jian-Xun Zhang, Suck-Joo Na. The mechanical properties and interface bonding mechanism of Molybdenum/SUS304L by laser beam welding with nickel interlayer [J]. Materials and Design, 2019, 182: 108002.

[57] Jie Ning, Lin-Jie Zhang*, Cheng-qian Han, Hai-Bo Zhang, Xiao-Wei Lei, Bai-Feng Han. Fiber laser welding characteristics of the butt welded joint of novel ultralight Mg-10.1Li-3.1Al-2.9Zn alloy [J]. Materials Research Express, 2019, 6(10): 106545.

[56] Zhifen Zhang, Linjie Zhang, Guangrui Wen*. Study of inner porosity detection for Al-Mg alloy in arc welding through on-line optical spectroscopy: Correlation and feature reduction [J]. Journal of Manufacturing Processes. 2019, 39: 79-92.

[55] Ning J, Zhang LJ*, Yin XQ, Zhang JX, Na SJ. Mechanism study on the effects of power modulation on energy coupling efficiency in infrared laser welding of high-reflectivity materials [J], Materials & Design, 2019, 178(15): 10871.

[54] Ning J, Zhang LJ*, Yang JN, Yin XQ, Wang XW, Wu J. Characteristics of multi-pass narrow-gap laser welding of D406A ultra-high strength steel [J]. J Mater Process Tech, 2019, 270: 168-181.

[53] Ning J, Hong KM, Inamke GV, Shin YC*, Zhang LJ. Analysis of microstructure and mechanical strength of lap joints of TZM alloy welded by a fiber laser [J]. J Manuf Process, 2019, 39: 146-159.

[52] Zhang Lin-Jie, Liu Jiang-Zhe*, Bai Qing-Lin, Wang Xue-Wu, Sun Yuan-Jun, Li Si-Gong, Gong Xing, Effect of preheating on the microstructure and properties of fiber laser welded girth joint of thin-walled nanostructured Mo alloy [J], International Journal of Refractory Metals and Hard Materials, 2019, 78: 219-227.

[51] Lin-Jie Zhang, Jun-Yu Pei*, Liang-Liang Zhang, Jian Long, Jian-Xun Zhang, Suck-Joo Na, Laser seal welding of end plug to thin-walled nanostructured high-strength molybdenum alloy cladding with a zirconium interlayer [J], Journal of Materials Processing Technology, 2019, 267: 338-347.

[50] Lin-Jie Zhang, Guang-Feng Lu*, Jie Ning, Qi Zhu, Jian-Xun Zhang, Suck-Joo Na, Effects of minor Zr addition on the microstructure and mechanical properties of laser welded dissimilar joint of titanium and molybdenum [J], Materials Science & Engineering A, 2019, 742: 788-797.

[49] Zhang Linjie, Lu Guangfeng*, Ning Jie, Zhang Liangliang, Long Jian, Zhang Guifeng, Influence of Beam Offset on Dissimilar Laser Welding of Molybdenum to Titanium[J], Materials, 2018, 11(10): 1852.

[48]Zhang L J, Pei J Y*, Long J, et al. Effects of Laser Welding and Post-Weld Heat Treatment on Microstructure and Mechanical Properties of Aged Ti55531 Alloy [J]. Materials, 2018, 11(10): 1907.

[47] Yang J N, Zhang L J*, Ning J, et al. Fiber laser welding characteristics of commercially pure zirconium (R60702) and structure-mechanics-corrosion performances of the joint [J]. International Journal of Refractory Metals & Hard Materials, 2018, 73: 58-73.

[46] Gao X L, Liu J, Zhang L J. Dissimilar metal welding of Ti6Al4V and Inconel 718 through pulsed laser welding-induced eutectic reaction technology [J]. International Journal of Advanced Manufacturing Technology, 2018, 96(1-4): 1061-1071.

[45] Lu G F, Zhang L J*, Pei Y, Ning J, Zhang J X. Study on the Size Effects of H-Shaped Fusion Zone of Fiber Laser Welded AZ31 Joint [J]. Metals, 2018, 8: 198.

[44] Liu J Z, Zhang L J*, Yang H X, et al. Enhancement of corrosion protection performance of SUS304/Q235B dissimilar metals lap joint through fiber laser [J]. International Journal of Advanced Manufacturing Technology, 2018, 96(1–4): 789-802.

[43] Jian-Nan Yang, Lin-Jie Zhang*, Jie Ning, Qing-Lin Bai, Xian-Qing Yin, Jian-Xun Zhang. Single pass laser-MIG hybrid welding of 8-mm thick pure copper (T2) without preheating: Microstructure and properties [J]. Applied Thermal Engineering, 2017,126: 867–883.

[42] Ning-Nian Gou, Lin-Jie Zhang*, Jian-Xun Zhang. Increased quality and welding efficiency of laser butt welding of 2205/X65 bimetallic sheets with a lagging MIG arc [J]. Journal of Materials Processing Technology, 2017, (Available online 16 August 2017).

[41] Ning Jie, Zhang Linjie*, Zhang Xingjun. Energy Coupling Behavior in Modulated Fiber Laser Welding of High Reflectivity AZ31 Magnesium Alloy [J]. RARE METAL MATERIALS AND ENGINEERING, 2017, 46(5): 1437-1444.

[40] Jian-Nan Yang, Lin-Jie Zhang*, Jie Ning, Qing-Lin Bai, Xian-Qing Yin, Jian-Xun Zhang. Single-pass hybrid laser-MIG welding of 8-mm-thick pure copper (T2) without preheating: weld geometry and integrity [J]. International Journal of Advanced Manufacturing Technology, 2017,91(9-12):3749-3773

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[1] Linjie Zhang*, Jianxun Zhang, et al. Numerical and experimental study of the effects of side assisting gas during laser welding [J]. Modelling and Simulation in Materials Science and Engineering, 2006, 14(5): 875-890.