Optimizing microstructure and mechanical properties in additively manufactured 18Ni (300) maraging steel by controlling strengthening agents

Abstract

Abstract

This study investigated the microstructural and mechanical behavior of ultrahigh-strength 18Ni (300) maraging steel manufactured using laser powder bed fusion (L-PBF) and subjected to various heat treatments (HTs). Four distinct HTs, including direct aging (DA), solution treatment with aging (S-A), cyclic austenitization with aging (CA-A), and solution treatment prior to both CA and A (S-CA-A), were designed based on thermodynamic calculations and dilatation tests to enhance strengthening mechanisms. Microstructural characteristics were analyzed through electron backscatter diffraction, transmission electron microscopy, electron probe microanalysis, and X-ray diffraction. Mechanical properties such as hardness, tensile strength, and impact toughness were evaluated and correlated with the microstructure. The DA treatment significantly refined the microstructure and promoted austenite reversion, while the CA-A treatment resulted in a coarser structure with higher austenite content. The DA and CA-A treatments provided an optimal combination of strength (2 GPa) and moderate ductility (6%). Physical models were utilized to relate yield strengths to microstructural characteristics, highlighting the strengthening effect of second-phase particles. Empirical equations based on power law and exponential functions were assessed for modeling strain-hardening behavior. CA increased austenite fractions, with CA-A and S-CA-A cycles showing 43.7% and 46.3%, respectively. Laves-phase particles reduced the steel’s impact energy absorption, decreasing toughness.