Abstract AISI 301 stainless steel is a metastable austenitic stainless steel and has the Md30 temperature of approximately 67°C, i.e., the temperature at which 50% of the austenite phase transforms into martensite during tensile testing at a true strain of 0.3. As a result, rolling and tension testing of 301 stainless steel would strain-induce transformation of γ to α'- and ε- martensites at room temperature. In the present study, the base metal (the B specimen) and laser welded specimen (the W specimen) were subjected to either cold rolling at 25°C (the B-CR and W-CR specimens) or warm rolling at 150°C (the B-HR and W-HR specimens) to reach a 30% reduction in thickness. The specimens were then thermally hydrogen charged at 300°C, or treated with an air furnace heat at 300°C (without hydrogen charging). Under various processing conditions, the internal hydrogen embrittlement (IHE) of the specimens was evaluated by the notch tensile test in air. The notch tensile properties of the specimens after heat treating at 300°C in air furnace showed insignificant differences to the specimens without heat treatment. Increasing the heat treatment temperature to 450°C, the tensile strength of the B-CR and W-CR specimens significantly reduced because the carbides (Cr23C6) precipitated at the grain boundaries. After cold rolling , the specimens generated many defects in the matrix, which resulted in a decrease in temperature for carbide precipitation, leading to weakened grain boundary regions. For the B specimen, hydrogen atoms were trapped at the grain and twain boundaries after thermal hydrogen charging at 300°C. These locations fractured easily during the notch tensile test due to the formation of brittle α'-martensite. The susceptibility to IHE of the B specimens under various rolling conditions was closely related to their microstructure. The B-CR specimen transformed into about 26% of α', which has worse resistance to IHE than the γ and ε phases. The B-HR only formed ε-martensite, the martrix was mainly γ phase so that exhibited lower susceptibility to IHE than the B-CR specimen. The strain-induced α'-martensite led to higher IHE of the B-CR specimen. As for the welded specimens, a small amount of residual δ-ferrite still existed during the weld solidification process. The γ/δ interfaces increased the trapping sites for hydrogen, as a result, the W specimen and its rolled specimens (the W-CR and W-HR specimens) would exhibit lower IHE than corresponding base metal specimens (the B, B-CR and B-HR specimens). The notch fracture surface of the B and W specimens without carbides precipitation showed dimple fracture after the air furnace heat treatment. The fracture surface displayed intergranular fracture (as seen in B-CR specimen after air furnace heat treatment at 450°C) was resulted from the carbides precipitated at grain boundaries. As for the thermal hydrogen charging specimens, the fracture surface of regions that were influenced by hydrogen exhibited brittle fracture with many secondary cracks. The strain-induced α' transformation localized in a narrow region in front of the notch tips indicates that hydrogen promotes localized plastic deformation, which agrees with the Hydrogen Enhanced Localized Plasticity (HELP) theory. If the thermal hydrogen charging temperature was increased, the hydrogen content in all specimens increased and the amount of α' transformation decreased, resulting in the localized plastic deformation more obviously.