Hydrogen embrittlement is a concern for using high-strength steels in load-bearing applications. Through the study of individual screw dislocations in alpha-iron, it has been found that hydrogen enhances the motion of screw dislocations, with the critical stress for initiating dislocation motion being lower in a hydrogen atmosphere compared to a vacuum environment. Moreover, cyclic loading and unloading helps to remove trapped hydrogen, allowing the dislocation to regain its original behavior.
Hydrogen embrittlement jeopardizes the use of high-strength steels in critical load-bearing applications. However, uncertainty regarding how hydrogen affects dislocation motion, owing to the lack of quantitative experimental evidence, hinders our understanding of hydrogen embrittlement. Here, by studying the well-controlled, cyclic, bow-out motions of individual screw dislocations in alpha-iron, we find that the critical stress for initiating dislocation motion in a 2 Pa electron-beam-excited H-2 atmosphere is 27-43% lower than that in a vacuum environment, proving that hydrogen enhances screw dislocation motion. Moreover, we find that aside from vacuum degassing, cyclic loading and unloading facilitates the de-trapping of hydrogen, allowing the dislocation to regain its hydrogen-free behaviour. These findings at the individual dislocation level can inform hydrogen embrittlement modelling and guide the design of hydrogen-resistant steels. Screw dislocations in alpha-iron move more easily in the presence of hydrogen, as evidenced by real-time imaging using quantitative transmission electron microscopy.
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