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Excellent combination of compressive strength and strain of AlCrFeNi MPEAs via adding Ti and V

Mingze Wang, Zhiqin Wen, Linsen Liang, Weiming Chen, Huaxuan Mo, Gaoxiang Wei, Yuhong Zhao

2023Journal of Alloys and Compounds11 citationsDOIOpen Access PDF

Abstract

In the current work, the influences of 12% X (X = Ti, V and Ti+V) on the structure and mechanical properties for AlCrFeNi matrix are compared in parallel. After mixing different component, parent phases (NiAl + Cr-Fe) of (AlCrFeNi) 88% X 12% multi-principal element alloys (MPEAs) can't result in phases separation. Nevertheless, 12 at% Ti- and V-mixed MPEAs lead to extra strengthening through new precipitating phases of L2 1 (Ni 2 TiAl) and BCC (Fe-V). For (AlCrFeNi) 88% Ti 6% V 6% , the two precipitating phases promote the synergistic strengthening of the strength and compressive strain . Ti is more effective than V in enhancing grain boundary energy of matrix, because Ti can induce more negative enthalpy of mixing, which makes the aggregation easier. Following identical mixing content, V causes pronounced solid solution strengthening but does not benefit the grain boundary strengthening, triggering an increase in ultimate strength of AlCrFeNi 88% V 12% . Significantly, the effectiveness of coordination strengthening is boosted by mixing 6%Ti+ 6%V. (AlCrFeNi) 88% Ti 6% V 6% has excellent compressive yield strength and strain, which is 1403.4 MPa and 23.1%, respectively. Our present analysis suggests that strengthening mechanism is applicable to explain the differences in nano interstitial structure, low Ti diffusion and non-equilibrium pinning effect of cooperative reinforcement of BCC (Fe-V) and L2 1 (Ni 2 TiAl) phases.

Topics & Concepts

Materials scienceNialSolid solution strengtheningCompressive strengthSolid solutionGrain boundaryMixing (physics)Ultimate tensile strengthDiffusionComposite materialMetallurgyMicrostructureThermodynamicsIntermetallicAlloyPhysicsQuantum mechanicsHigh Entropy Alloys StudiesAluminum Alloys Composites PropertiesHigh-Temperature Coating Behaviors