OwenW. S.: ‘Can a simple heat treatment help to save Detroit?’, Met. Technol., 1970, 7, 1–13.
4.
KuziakR., KawallaR. and WaenglerS.: ‘Advanced high strength steels for automotive industry’, Arch. Civ. Mech. Eng., 2008, 8, 103–117.
5.
KhanM. I., KuntzM. L., SuP., GerlichA., NorthT. and ZhouY.: ‘Resistance and friction stir spot welding of DP600: A comparative study’, Sci. Technol. Weld. Join., 2007, 12, 175–182.
6.
MatsumuraO., SakumaY. and TakechiH.: ‘Enhancement of elongation by retained austenite in intercritical annealed 0.4C-1.5Si-0.8Mn steel’, Trans. Iron Steel Inst. of Jpn, 1987, 27, 570–579.
7.
BhadeshiaH. K. D. H.: ‘Bainite in steels: theory and practice’, 3rd ed., 2015, Leeds, UK, Maney Publishing.
8.
CretteurL., KorkukA. I. and Tosal-MartínezL.: ‘Improvement of weldability of TRIP steels by use of in-situ pre- and post-heat treatments’, Steel Res, 2002, 73, 314–319.
9.
SahaD. C., HanS., ChinK. G., ChoiI. and ParkY. D.: ‘Weldability evaluation and microstructure analysis of resistance-spot-welded high-mn steel in automotive application’, Steel Research Int, 2012, 83, 352–357.
10.
BealC., KleberX., FabregueD. and BouzekriM.: ‘Liquid zinc embrittlement of a high-manganese-content TWIP steel’, Phil. Mag. Lett., 2011, 91, 297–303.
11.
BealC., KleberX., FabregueD. and BouzekriM.: ‘Liquid zinc embrittlement of twinning-induced plasticity steel’, Scripta Mater., 2012, 1030–1033.
12.
BealC., KleberX., FabregueD. and BouzekriM.: ‘Embrittlement of a zinc coated high manganese TWIP steel’, Mater. Sci. Eng. A-Struct., 2012, 543, 76–83.
13.
BealC., KleberX., FabregueD. and BouzekriM.: ‘Embrittlement of a high manganese TWIP steel in the presence of liquid zinc’, Mater. Sci., 2012, 706, Forum, 2041–2046.
14.
RonceryL. M., WeberS. and TheisenW.: ‘Welding of twinning-induced plasticity steels’, Scripta Mater, 2012, 66, 997–1001.
15.
ZhaoH. and DebRoyT.: ‘Pore formation during laser beam welding of die-cast magnesium alloy AM60B-mechanism and remedy’, Welding J, 2001, 80, 204–210.
ZhaoH., WhiteD. R. and DebRoyT.: ‘Current issues and problems in laser welding of automotive aluminium alloys’, Internat. Mater. Rev, 1999, 44, 238–266.
19.
DebRoyT. and BhadeshiaH. K. D. H.: ‘Friction stir welding of dissimilar alloys’, Sci. Technol. Weld. Join., 2010, 15, 266–270.
20.
RajinikanthV., MukherjeeK., ChowdhuryS. G., SchiebahnA., HarmsA. and BleckW.: ‘Mechanical property and microstructure of resistance spot welded twinning induced plasticity-dual phase steels joint’, 18, 2013, 485–491.
21.
AshfaqM. and RaoK. J.: ‘Comparing bond formation mechanism between similar and dissimilar aluminium alloy friction welds’, Mater. Sci. Technol., 2014, 30, 329–338.
22.
WeiS. T., LvD., LiuR. D., LinL., XuR. J., GuoJ. Y. and WangK. Q.: ‘Similar and dissimilar resistance spot welding of advanced high strength steels: welding and heat treatment procedures, structure and mechanical properties’, Sci. Technol. Weld. Join., 2014, 19, 427–435.
23.
WeiS. T., LiuR. D., LvD., LinL., XuR. J., GuoJ. Y., WangK. Q. and LuX. F.: ‘Weldability and mechanical properties of similar and dissimilar resistance spot welds of three-layer advanced high strength steels’, Sci. Technol. Weld. Join., 2015, 20, 20–26.
24.
WangJ., FengJ. C. and WangY. X.: ‘Microstructure of Al-Mg dissimilar weld made by cold metal transfer mig welding’, Mater. Sci. Technol., 2008, 24, 827–831.
25.
LinQ., ZhouY., CaoR. and ChenJ. H.: ‘Wetting of steel by Al 4043 alloys in cold metal transfer process’, Sci. Technol. Weld. Join., 2015, 20, 454–459.
26.
BorchersT. E., SeidA., BabuS. S., ShaferP. and ZhangW.: ‘Effect of filler metal and post-weld friction stir processing on stress corrosion cracking susceptibility of Al-Zn-Mg arc welds’, Sci. Technol. Weld. Join, 2015, 20, 460–467.
27.
WakabayashiC. and MiyazakiY.: ‘Strengthening spot weld joint by auto-tempering acceleration at heat affected zone’, Sci. Technol. Weld. Join, 2015, 20, 468–472.
28.
YangH. S. and BhadeshiaH. K. D. H.: ‘Austenite grain size and the martensite-start temperature’, 493–495; 2009, Scripta Mater.
29.
SvenssonL. E., KarlssonL. and SöderR.: ‘Welding enabling light weight design of heavy vehicle chassis’, Sci. Technol. Weld. Join, 2015, 20, 473–482.
30.
BarnesN., JosephT. and MendezP. F.: ‘Issues associated with welding/surfacing of large mobile mining equipment for use in oil sands applications’, Sci. Technol. Weld. Join, 2015, 20, 483–493.
31.
WeiS., LiuR., LvD., LinL., LuX. and DingS.: ‘E?ects of welding parameters on fibre laser lap weldability of galvanized DP 1000 steel’, Sci. Technol. Weld. Join., 2015, 20, 433–442.
32.
ChenY., ChenJ., AmirkhizB. S., WorswickM. J. and GerlichA.: ‘Microstructures and properties of Mg-alloy/DP600 steel dissimilar refill friction stir spot welds’, Sci. Technol. Weld. Join, 2015, 20, 494–501.
33.
PouranvariM., AbadiM. A. S. and MarashiP.: ‘Welding metallurgy of stainless steels during resistance spot welding-Part I: The fusion zone’, Sci. Technol. Weld. Join, 2015, 20, 502–511.
34.
Alizadeh-ShM., PouranvariM. and MarashiS. P. H.: ‘Welding metallurgy of stainless steels during resistance spot welding-Part II: The heat affected zone and mechanical performance’, Sci. Technol. Weld. Join, 2015, 20, 512–521.
35.
ChenK. and ZhangY.: ‘Numerical analysis of temperature distribution during ultrasonic welding process for dissimilar automotive alloys’, Sci. Technol. Weld. Join, 2015, 20, 522–531.
