Diffusional model of expanded austenite layer growth on AISI 316L stainless steel during low-temperature hybrid thermochemical treatment Online publication date: Wed, 27-Oct-2021
by Esa Haruman; Annissa Fanya; Mohd Shahriman Adenan
International Journal of Computational Materials Science and Surface Engineering (IJCMSSE), Vol. 10, No. 2, 2021
Abstract: A simultaneous nitrogen and carbon diffusional model in AISI 316L stainless steel is presented in this numerical study to simulate expanded austenite layer growth developed during hybrid thermochemical treatment. This numerical model has not been previously discussed using a gaseous process. The present work considered the trapping-detrapping phenomenon, the concentration-dependent diffusion coefficient, and the composition-induced stress gradient as the boundary parameters. The study revealed that the stress gradient effect accelerated the diffusion rate of nitrogen and carbon species. The trapping-detrapping phenomenon caused the diffusional curvature to consist of convex and concave shapes, which differ from those derived from the Fick's 2nd law. The present model confirmed previous experimental evidence that the developed layer would be structured with nitrogen-enriched expanded austenite on the top of the layer and carbon-enriched expanded austenite underneath. This novel model can be considered in designing the hybrid thermochemical treatments using a gaseous process.
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