Microstructural evolution, deformation modes, and failure mechanisms in laser powder bed fusion processed nickel-free and 316L stainless steels - UTU Tutkimustietojärjestelmä

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Microstructural evolution, deformation modes, and failure mechanisms in laser powder bed fusion processed nickel-free and 316L stainless steels

Tekijät: Suman, Siddharth; Goel, Sneha; Rantala, Juhani; Nurmela, Asta; Anand, Abhinav; Ganvir, Ashish; Sui, Ran; Que, Zaiqing

Kustantaja: Elsevier BV

Julkaisuvuosi: 2025

Lehti:: Materials and Design

Artikkelin numero: 114882

Vuosikerta: 259

ISSN: 0264-1275

eISSN: 1873-4197

DOI: https://doi.org/10.1016/j.matdes.2025.114882

Verkko-osoite: https://doi.org/10.1016/j.matdes.2025.114882

Rinnakkaistallenteen osoite: https://research.utu.fi/converis/portal/detail/Publication/504914818

Tiivistelmä

This study investigates the influence of microstructures on mechanical behavior and failure mechanisms of laser based powder bed fusion processed nickel-free and 316L stainless steels using small punch testing, nanoindentation, and miniaturized tensile testing. The as-printed 316L with a fully austenitic structure and high-density dislocation cells exhibited a nanohardness of 3.0 GPa, tensile strength of 600 MPa, and elongation close to 60 %, with failure occurring through ductile microvoid coalescence. In contrast, the as-printed nickel-free stainless steel with a fully ferritic matrix and random dislocation networks showed a high nanohardness of 4.94 GPa, but poor ductility of 2 % and transgranular cleavage fracture. Heat treatment at 950 °C for 30 min transformed the nickel-free steel into a duplex microstructure (56 % ferrite and 41 % austenite, with a minor 3 % Chi phase), reducing dislocation density and inducing stacking faults. This resulted in moderate improvement in tensile strength as well as ductility and a mixed fracture mode. Post-mortem analysis revealed that Chi phase assisted crack initiation and strain localization was observed near coarse grains. The evolution of low-angle to high-angle grain and twin boundaries promoted plastic deformation. These results highlight the importance of phase engineering and microstructural control in optimizing the ductility and toughness of nickel-free steels.

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Julkaisussa olevat rahoitustiedot:
VTT acknowledges the funding by the European Union – NextGenerationEU. University of Turku acknowledges the funding support from Tenure-Track grant to Prof. Ashish Ganvir; Research Council of Finland as well as European Council for co-funded M.ERANET 2022, GREEN-BAT (2022-2025) project and Research Council of Finland funded SOLACE, 360540 (2024-2028) project.