Confined necking and improved tensile ductility in heterostructured bi-metallic steels made by additive manufacturing
Xiao Feng Shang, Chenwei Shao, S.S. Dash, Lulu Guo, Joseph Agyapong, Lizhong Lang, Alec Chen, Sang Bum Yi, Tianyi Lyu, Hao Chen, Solomon Boakye-Yiadom, Yu Zou
Abstract
Achieving high tensile ductility is crucial in structural materials, as it supports reliable load-bearing performance and good formability. Steels, the most widely used structural metals, show a wide range of elongation to failure, from a few percent to a few tens of percent. Recently, heterostructured materials (HMs) have been reported to exhibit superior tensile properties that surpass those of their homogeneous counterparts. Classical HMs with heterogeneity in the length scale less than a few hundred nanometres attribute their enhanced mechanical performance mainly to the hetero-deformation induced (HDI) hardening. However, the underlying mechanisms for HMs with mesoscale heterogeneities, i.e., in the length scale of a few hundred micrometers, are overlooked. Recent advances in additive manufacturing (AM) have provided opportunities to fabricate HMs over the mesoscale range with structural complexity. In this work, we employ the AM method to fabricate a type of mesoscale HM: bi-metallic heterostructured steels (HSs), consisting of 316L and PH17-4 stainless steels with distinct tensile strength and ductility. By tuning the ratios and fractions of 316L/PH17-4, we achieved 27.3%, 11.5%, and 1.8% improvements in the tensile ductility, ultimate tensile strength, and yield strength over 316L, respectively. Such enhanced tensile properties are mainly attributed to (i) confined-necking co-deformation, where the necking of PH17-4 is confined and delayed by 316L, offering more work hardening to the whole sample, (ii) switching between necking-induced and shear-induced failure modes, and (iii) the HDI hardening effect. This study paves the way for understanding and designing bi-metallic HSs with improved tensile properties using AM methods.