Microstructure and Mechanism of Copper Layer Processed with Laser Remelting and Electrochemical Deposition Interaction Process

Tingchao Xiong; Yanyi Yin; Danhua Lu; Guolong Wu; Ye Wang; Jianhua Yao

doi:10.3788/CJL220615

[1] Wei C C, Fan C T, Chiang T H et al. Direct plated copper metallization substrate and its application on microwave circuits[J]. Microwave Journal, 53, 84-94(2013).

[2] Schulz-Harder J. Advanced DBC (direct bonded copper) substrates for high power and high voltage electronics[C], 230-231(2006).

[3] Schulz-Harder J. Advantages and new development of direct bonded copper substrates[J]. Microelectronics Reliability, 43, 359-365(2003).

[4] Tsai M Y, Huang P S, Lin C H et al. Mechanical design and analysis of direct-plated-copper aluminum nitride substrates for enhancing thermal reliability[J]. Microelectronics Reliability, 55, 2589-2595(2015).

[5] Hao Z L. Research on DPC ceramic substrate fabrication technology using electroless plating[D](2015).

[6] Li D H, Liu B L, Zou J C et al. Improvement of osseointegration of titanium dental implants by a modified sandblasting surface treatment: an in vivo interfacial biomechanics study[J]. Implant Dentistry, 8, 289-294(1999).

[7] Bouzakis K D, Skordaris G, Mirisidis I et al. Cutting performance improvement through micro-blasting on well-adherent PVD films on cemented carbide inserts[J]. Surface and Coatings Technology, 200, 1879-1884(2005).

[8] Liu Y M, Li P, Li R H. Process for electroplating copper and silver on titanium alloy[J]. Electroplating & Finishing, 34, 30-33(2015).

[9] Yuan Y C, Zhao X S. Effects of different pretreatment processes on electroplating of nickel–phosphorus alloy on titanium alloy[J]. Electroplating & Finishing, 39, 536-539(2020).

[10] Jiang H T, Shao Z C, Wei S Q. Research progress of surface treatment techniques for titanium alloys[J]. Plating & Finishing, 32, 15-20(2010).

[11] Sun Z H, Liu Y H, Zhang X Y et al. A review of electroplating technology on titanium and titanium alloys[J]. Corrosion & Protection, 26, 493-496(2005).

[12] Liang Y. The influence of heat treatment temperature/time on the structure of TC4 titanium alloy copper coating[D](2015).

[13] Fu Y H, Li Y P, Yang X T. Effects of pickling as pretreatment and heat treatment as post-treatment on cyanide-free gold electroplating of TC4 titanium alloy[J]. Electroplating & Finishing, 37, 375-380(2018).

[14] Lu D H, Xu Y L, Wu G L et al. Effect of laser melting pretreatment on process and corrosion resistance of electrodeposited copper on titanium alloy surface[J]. Surface Technology, 50, 83-92, 110(2021).

[15] Bian Y C, Peng Y B, Song L F et al. Heterogeneity of 316L/IN718 formed via selective laser melting based on laser remelting optimization process[J]. Chinese Journal of Lasers, 48, 1802009(2021).

[16] Wang Y F, Zhao X Y, Lu W J et al. Microstructure and properties of high speed laser cladding stainless steel coating on sucker rod coupling surfaces[J]. Chinese Journal of Lasers, 48, 0602114(2021).

[17] Wang J G, Gao S Y, Chen X S et al. Mechanical properties of A356 aluminum alloy after laser surface remelting[J]. Chinese Journal of Lasers, 47, 0402002(2020).

[18] Zhang P Z, Xu Z, Zhang G H et al. Study of surface burn-resistant Ti-Cu titanium alloy[J]. Rare Metal Materials and Engineering, 34, 162-165(2005).

[19] Yuan Q L. Surface titanizing and nickelizing of copper using double glow plasma surface alloying technique[D](2004).

[20] Uzunov T D, Stojanov S P, Lambov S I. Thin films of intermetallic Cu/Ti compounds and their possible uses[J]. Vacuum, 52, 321-325(1999).

[21] Wang D S, Huang Y H, Tian Z J et al. Effect of laser remelting on microstructure and properties of nanocrystalline nickel coating prepared by jet electrodepositing[J]. Chinese Journal of Lasers, 35, 142-146(2008).

[22] An G S, Li W S, Feng L et al. TGO growth behaviors and high-temperature oxidation resistance mechanism of thermal barrier coating after laser remelting[J/OL]. Transactions of Nonferrous Metals Society of China, 1-19. http://kns.cnki.net/kcms/detail/43.1238.TG.20211110.1152.002.html

[23] Guo S, Zhou Q, Peng Y et al. Study on strengthening mechanism of Ti/Cu electron beam welding[J]. Materials & Design, 121, 51-60(2017).

[24] Guo S, Luo T Y, Peng Y et al. Interface behavior and mechanical properties of Ti/Cu dissimilar metals welding by electron beam[J]. Transactions of the China Welding Institution, 40, 26-32, 162(2019).

[25] He H. Preparation of Ti(C, N) based cermet and the study on microstructure and property of Ti(C, N) based cermet/45 steel brazed joints[D](2018).

[26] Calle-Vallejo F, Koper M T M, Bandarenka A S. Tailoring the catalytic activity of electrodes with monolayer amounts of foreign metals[J]. Chemical Society Reviews, 42, 5210-5230(2013).

[27] Chen X J, Jiang L X, Peng B et al. Electrochemical behavior of ultrabattery negative electrode material[J]. Journal of Central South University (Science and Technology), 43, 2023-2028(2012).