Litcius/Paper detail

Evidence of Inverse Hall-Petch Behavior and Low Friction and Wear in High Entropy Alloys

Morgan R. Jones, Brendan Nation, John A. Wellington-Johnson, John F. Curry, Andrew Kustas, Ping Lu, Michael Chandross, Nicolas Argibay

2020Scientific Reports53 citationsDOIOpen Access PDF

Abstract

Abstract We present evidence of inverse Hall-Petch behavior for a single-phase high entropy alloy (CoCrFeMnNi) in ultra-high vacuum and show that it is associated with low friction coefficients (~0.3). Grain size measurements by STEM validate a recently proposed dynamic amorphization model that accurately predicts grain size-dependent shear strength in the inverse Hall-Petch regime. Wear rates in the initially soft (coarse grained) material were shown to be remarkably low (~10 –6 mm 3 /N-m), the lowest for any HEA tested in an inert environment where oxidation and the formation of mixed metal-oxide films is mitigated. The combined high wear resistance and low friction are linked to the formation of an ultra-nanocrystalline near-surface layer. The dynamic amorphization model was also used to predict an average high angle grain boundary energy (0.87 J/m 2 ). This value was used to explain cavitation-induced nanoporosity found in the highly deformed surface layer, a phenomenon that has been linked to superplasticity.

Topics & Concepts

Materials scienceNanocrystalline materialGrain sizeGrain boundary strengtheningInverseAlloyGrain boundarySuperplasticityHigh entropy alloysComposite materialMetallurgyMicrostructureNanotechnologyGeometryMathematicsHigh Entropy Alloys StudiesHigh-Temperature Coating BehaviorsDiamond and Carbon-based Materials Research