Hydrogen-induced fast fracture in a 1.5 GPa dual-phase steel

Abstract

This study clarifies the hydrogen embrittlement (HE) behavior in a 1.5 GPa ferrite-martensite dual-phase (DP) steel. Hydrogen pre-charging (3.8 mass ppm diffusible hydrogen), followed by slow strain tensile testing (10-4 s-1), resulted in a brittle fracture at 900 MPa within the elastic regime. Fractographic studies indicated that surface crack initiation consists of intergranular and quasi-cleavage morphology; site-specific transmission electron microscopy (TEM) investigations revealed sub-surface secondary crack blunting by ferrite. A mixed-mode morphology consisting of ductile and brittle features was observed adjacent to crack initiation. It differs from the previous investigation of uncharged DP steel, wherein a predominant brittle fracture was observed. Following significant crack growth, the pre-charged specimen exhibited predominant brittle fracture; site-specific TEM and transmission Kikuchi diffraction studies revealed 100 ferrite cleavage cracking. Electron backscatter diffraction studies were performed on the cross-sectional cracks. We explain the HE via hydrogen-induced fast fracture mechanism. During loading, hydrogen diffuses to the prior austenite grain boundary, resulting in hydrogen-induced decohesion. Subsequent hydrogen diffusion to the crack tip promotes brittle fracture at high crack velocity (>Vcrit). The high crack velocity effectively inhibits crack blunting via dislocation emission, ensuring sustained brittle crack growth even after hydrogen depletion at the crack tip, resulting in 100 ferrite cleavage cracking. Based on TEM observations, we explain the formation of river pattern features on the 100 cleavage surface.