Influence of plasma nitriding on hydrogen environment embrittlement of 1.4301 austenitic stainless steel

Abstract

The aim of this work was to study if hydrogen environment embrittlement of DIN 1.4301 austenitic stainless steel can be suppressed by a nitrided surface. DIN 1.4301 was plasma nitrided in a N 2/H 2 discharge. Nitriding produced 3-layered structure consisting of a γ N top layer, an intermediate γ/γ C-layer and a diffusion layer. It is assumed that the γ C phase was formed due to the decomposition of CO originating from the reactor walls and the subsequent incorporation of C into the material. The γ C phase is characterized by distinct XRD peaks and carbon contents between 0.5 and 4 wt.% as well as nitrogen contents between 0.5 and 8 wt.%. Plastic deformation of the plasma nitrided specimen showed cracks and some delamination of the γ N layer, whereas the γ/γ C-layer behaved in a very ductile manner. Even at a plastic deformation of 35% no cracks or any other damage was visible. A tensile test in gaseous hydrogen showed severe embrittlement of the unnitrided steel and the nitrided steel with a γ N layer. No cracks were observed in areas where just the γ/γ C-layer was present.