Litcius/Paper detail

An experimentally driven high-throughput approach to design refractory high-entropy alloys

Chanho Lee, Dongyue Xie, Benjamin K. Derby, Jon K. Baldwin, Christopher Tandoc, Osman EI Atwani, Yong‐Jie Hu, James A. Valdez, Nan Li, Saryu Fensin

2022Materials & Design29 citationsDOIOpen Access PDF

Abstract

High-entropy alloy (HEA) design strategies have been limited to theoretical/computational approaches due to their compositional complexity and extremely large compositional parameter space. In this work, we developed an experimentally driven, high-throughput, HEA design approach using a physical vapor deposition (PVD) technique and coupled it with nanomechanical testing to accelerate material design for structural applications. The PVD technique enabled the formation of a compositional gradient across a thin-film sample. Specifically, a 10 cm wafer was used to manufacture a continuous set of 80 HEA compositions within the Nb-Ti-V-Zr family using a single deposition cycle. By using the solid-solution strengthening theory and estimated parameter properties, the strength and ductility of these HEA compositions were quantitatively determined/predicted and then experimentally verified by nano-indentation hardness test. Consequently, 7 refractory HEA compositions were successfully down-selected, which has a high propensity to have a balanced mechanical property.

Topics & Concepts

Materials scienceHigh entropy alloysPhysical vapor depositionIndentationAlloyDuctility (Earth science)ThroughputWaferRefractory metalsThin filmComposite materialMetallurgyNanotechnologyCreepComputer scienceWirelessTelecommunicationsHigh Entropy Alloys StudiesMetal and Thin Film MechanicsHigh-Temperature Coating Behaviors
An experimentally driven high-throughput approach to design refractory high-entropy alloys | Litcius