The non-equilibrium cooling of 304 SS by TIG welding, making the formation of dendritic δ-ferrite in fusion zone (FZ), whereas the lath δ-ferrite formed in the heat affected zone (HAZ) that accompanied by high proportion of high-angle grain boundaries and precipitation hardening. Consequently, welded joint has higher strength and hardness compares to the base metal (BM), and fracture exhibits ductile intergranular. The slower cooling rate in HAZ promotes precipitation strengthening and refinement of δ-ferrite, inducing microhardness gradient distributed as HAZ > FZ > BM and effectively improve tensile strength. However, electrochemical measurements reveal FZ and HAZ are more susceptible to corrosion than the BM. Cr segregation and depletion surrounded δ-ferrite phase, lowering protection film formation on welding bead of γ-austenite.
AamaniSDasCRMarthaSK, et al.Influence of nitrogen on grain size-dependent sensitisation and corrosion resistance of 316L (N) austenitic stainless steels. Trans. Indian Inst. Met2022; 75: 2169–2177.
2.
AlcantaraASFábiánERFurkóM, et al.Corrosion resistance of TIG welded joints of stainless steels. Mater Sci Forum2017; 885: 190–195.
3.
SongIJeongGHKimSK, et al.Effects of autogenous gas tungsten arc welding (GTAW) on corrosion resistance of stainless steel 316L. Processes2024; 12: 1757.
4.
MirshekariGRTavakoliEAtapourM, et al.Microstructure and corrosion behavior of multipass gas tungsten arc welded 304L stainless steel. Mater. Des2014; 55: 905–911.
KaulRGaneshPSinghN, et al.Effect of active flux addition on laser welding of austenitic stainless steel. Sci Technol Weld Joining2007; 12: 127–137.
7.
ParkSHC, et al.Microstructural characterisation of stir zone containing residual ferrite in friction stir welded 304 austenitic stainless steel. Sci Technol Weld Joining2005; 10: 550–556.
8.
MishraRSMaZY. Friction stir welding and processing. Mater. Sci. Eng. R Rep2005; 50: 1–78.
9.
FouadRAHabbaMIAElshaghoulYGY, et al.Comparative analysis of filler metals on microstructure and mechanical performance of TIG-welded AISI 201 austenitic stainless steel joints. Sci Technol Weld Joining2024; 29: 356–336.
10.
VashishthaHTaiwadeRVKhatirkarRK, et al.Effect of austenitic fillers on microstructural and mechanical properties of ultra-low nickel austenitic stainless steel. Sci Technol Weld Joining2016; 21: 331–337.
11.
Hossein NedjadSYildizMSabooriA. Solidification behaviour of austenitic stainless steels during welding and directed energy deposition. Sci Technol Weld Joining2023; 28: 1–17.
12.
ZachariaTDavidSAVitekJM, et al.Heat transfer during nd: yag pulsed laser welding and its effect on solidification structure of austenitic stainless steels. Metall Trans A1989; 20: 957–967.
13.
LeeJHYamashitaSOguraT, et al.Effect of welding condition on solidification cracking behaviour in austenitic stainless steel. Sci Technol Weld Joining2021; 26: 84–90.
14.
JiangYMTanHWangZY, et al.Influence of creq/nieq on pitting corrosion resistance and mechanical properties of UNS S32304 duplex stainless steel welded joints. Corros Sci2013; 70: 252–259.
15.
ChuaiphanWCSrijaroenpramongLS. Optimization of gas tungsten arc welding parameters for the dissimilar welding between AISI 304 and AISI 201 stainless steels. Defence Technology2019; 15: 170–178.
16.
ChenMHChouCP. Effect of thermal cycles on ferrite content of austenitic stainless steel. Sci Technol Weld Joining1999; 4: 58–62.
17.
CaiYLuoZZengY. Influence of deep cryogenic treatment on the microstructure and properties of AISI304 austenitic stainless steel A-TIG weld. Sci Technol Weld Joining2017; 22: 236–243.
18.
LeeJ-HYamashitaSOguraT, et al.Effect of heat dissipation on solidification cracking behaviour of austenitic stainless steel during gas tungsten arc welding. Sci Technol Weld Joining2021; 26: 455–460.
19.
VitekJMDasguptaADavidSA. Microstructural modification of austenitic stainless steels by rapid solidification. Metall Trans A1983; 14: 1833–1841.
20.
YeYYangBRYangYH, et al.Research on the formation, microstructure, and properties of 304 stainless steel AC-DC hybrid TIG welding. Metals (Basel)2023; 13: 1127.
21.
InoueH, et al.Formation mechanism of vermicular and lacy ferrite in austenitic stainless steel weld metals. Sci Technol Weld Joining2000; 5: 385–396.
22.
FouadRAHabbaMIAElshaghoulYGY, et al.Comparative analysis of filler metals on microstructure and mechanical performance of TIG-welded AISI 201 austenitic stainless steel joints. Sci Technol Weld Joining2024; 29: 356–367.
23.
García-GarcíaVReyes-CalderónFFrasco-GarcíaOD, et al.Mechanical behavior of austenitic stainless-steel welds with variable content of δ-ferrite in the heat-affected zone, eng. Fail Anal2022; 140: 106618.
24.
YuWXLiuBXChenCX, et al.Microstructure and mechanical properties of stainless steel clad plate welding joints by different welding processes. Sci Technol Weld Joining2020; 25: 571–580.
25.
SilvaLDLE, et al.Effects of mechanical stress on the corrosion behaviour of an austenitic stainless steel welded joint – stress corrosion cracking susceptibility. Corros. Sci2025; 244: 112629.
26.
LiangSMYuPZhangF, et al.Back diffusion resisting solidification cracking in austenitic stainless steels. Sci Technol Weld Joining2021; 26: 606–613.
27.
KadoiKKogureMInoueH. Effect of ferrite morphology on pitting corrosion resistance of austenitic stainless steel weld metals. Corros. Sci2023; 221: 111356.
28.
GoochTG. Corrosion Behavior of Welded Stainless Steel. AwS 76th Annual Meetin,G April 3-7, 1995, Cleveland, Ohio. 135-154.
29.
BanovicSWDupontJNMarderAR. Dilution and microsegregation in dissimilar metal welds between super austenitic stainless steel and nickel base alloys. Sci Technol Weld Joining2002; 7: 374–383.
30.
TanXSunXHJiangYM, et al.Effect of microstructure evolution caused by welding process on pitting behavior of 321 stainless steel, corros. Sci2025; 243: 112591.
31.
ZengYGHuYJWangZS, et al.Performance analysis and material selection of stainless steel expansion joints for power grid equipment. J Phys: Conf Ser2021; 2076: 012097.
32.
MonteiroSNNascimentoLFCLimaEP, et al.Strengthening of stainless steel weldment by high temperature precipitation. J. Mater. Research Techno2017; 6: 385–389.
33.
JiangJZhuLH. Strengthening mechanisms of precipitates in S30432 heat-resistant steel during short-term aging. Mater. Sci. Eng.: A2012; 539: 170–176.
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