Abstract
In the present study, the environmental sensitivity under tensile loading of a high-performance Fe-40Al alloy prepared by mechanical alloying is investigated. Testing performed under various environmental conditions reveals a significant loss of ductility in the presence of a moist atmosphere without concomitant change in the stress-strain relationship and fracture mode. Furthermore, this embrittlement is essentially controlled by water vapor. In addition, it is shown that increasing the strain rate improves the final elongation in air up to the intrinsic ductility determined in an inert atmosphere. This embrittlement is attributed to the hydrogen released by the dissociation of water vapor molecules and subsequently swept into the material by mobile dislocations. Tests were designed and carried out specifically to assess the respective roles of exposure duration and straining in this process. Finally, a model is proposed to account for this phenomenon and the mechanisms are discussed.
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