discussion3.1. Microstructure chara

discussion3.1. Microstructure characterizationFig. 2 shows the optical microstructures in the different zonesof the DSS joint welded by three different welding techniques.In the DSS (S31803) welding joints, the austenite contains twotypes: primary austenite and 2. The primary austenite are directlysolidified from molten metals among ferritic dendrites as well asformed from the subsequent solid-state phase transition of the fer-rite into the austenite. According to precipitation mechanism andmorphology, the primary austenite are divided into grain bound-ary austenite, Widmanstätten austenite, intragranular austenite,and partially transformed austenite. The allotriomorphic austenitefirst begun to nucleate and grew at prior ferrite boundaries, whichwere named as grain boundary austenite [41,42]. When coolingcontinued and the amount of grain boundary austenite increased,the available nucleation sites at the ferrite boundaries decreasedand then if time permitted, new nuclei begun to initiate from grainboundary austenite, and grew towards the ferrite side in the formof side-plate Widmanstätten austenite [41]. If with sufficient timeafter reheating from subsequent beads, the intragranular austenitecan form at the Ni/N-rich regions in the ferrite grain. The intra-granular austenite formation needs more undercooling as a drivingforce compared to the grain boundary austenite and Widmanstät-ten austenite because of its higher activation energy for latticediffusion, as reported by Eghlimi et al. [42]. Since lattice diffusionoccurs much slower than grain boundary diffusion, the intragran-ular austenite growth is limited, thereby resulting in finer grains,as shown in Fig. 2. The intragranular austenite generally nucleatesat the inclusions and dislocations or other small precipitates such