Abstract
Tuning deformation mechanisms is imperative to overcome the well-known strength-ductility paradigm. Twinning-induced plasticity (TWIP), transformation-induced plasticity (TRIP) and precipitate hardening have been investigated separately and have been altered to achieve exceptional strength or ductility in several alloy systems. In this study, we use a novel solid-state alloying method—friction stir alloying (FSA)—to tune the microstructure, and a composition of a TWIP high-entropy alloy by adding Ti, and thus activating site-specific deformation mechanisms that occur concomitantly in a single alloy. During the FSA process, grains of the as-cast face-centered cubic matrix were refined by high-temperature severe plastic deformation and, subsequently, a new alloy composition was obtained by dissolving Ti into the matrix. After annealing the FSA specimen at 900 °C, hard Ni–Ti rich precipitates formed to strengthen the alloy. An additional result was a Ni-depleted region in the vicinity of newly-formed precipitates. The reduction in Ni locally reduced the stacking fault energy, thus inducing TRIP-based deformation while the remaining matrix still deformed as a result of TWIP. Our current approach presents a novel microstructural architecture to design alloys, an approach that combines and optimizes local compositions such that multiple deformation mechanisms can be activated to enhance engineering properties.
Highlights
High-entropy alloys (HEAs) have attracted considerable interest since they were first conceptualized and synthesized by Yeh[1]
electron backscattered diffraction (EBSD) phase maps confirm that both as-cast and friction stir processing (FSP) conditions consist of a single phase of γ, which indicates that no phase transformation occurred during FSP
Grain refinement was observed after FSP as the average grain size of 13.7 ± 2.5 μm in as-cast condition reduced to 1.8 ± 0.6 μm in FSP condition
Summary
High-entropy alloys (HEAs) have attracted considerable interest since they were first conceptualized and synthesized by Yeh[1]. The preliminary study on TRIP-DP (dual phase)-HEA ( Fe50Mn30Co10Cr10 at.%, γ (FCC) and ε (HCP) phases) by Li et al.[4] demonstrated that both strength and ductility can be improved by a strain-induced γ to ε transformation Inspired by this finding, Nene et al.[9] modified the alloy composition by adding Si and increasing Cr (Fe42Mn28Co10Cr15Si5 at.%) and increasing metastability of the γ phase to capitalize on the TRIP effect. The FSA process used in the current work, utilizes the shear deformation during the solid-state processing, to distribute the additional desired alloying element into the matrix by non-equilibrium dissolution. The alloying of Ti resulted in formation of Ni3Ti precipitates which, on one hand, strengthened the material; and, they reduced Ni concentration around Ni3Ti precipitates, lowering the SFE enough to introduce an additional TRIP mechanism effect locally
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