Weak enthalpy-interaction-element-modulated NbMoTaW high-entropy alloy thin films

A local structure determines the properties in disordered solid solutions with simple crystal structure. Introducing a weak enthalpy-interaction-element will change the local structure evolution of refractory high-entropy alloy films, thereby bringing effects for the properties. Herein series of (NbMoTaW)(100-x)V-x (x = 0 similar to 30.5, at%) thin films were prepared by radio frequency magnetron sputtering, and systematic investigations of the films are carried out through combining the underlying microstructure, mechanical properties, and resistivity-temperature behavior. Furtherly, in accordance with the cluster-plus-glue-atom model, the present paper interpreted the local structure evolution with the film components changing. The results reveal that the excellent thermal stability of the films is originate from the enthalpy interaction, and the high stability of the refractory element itself. The V addition is free of crystal structure variation in the films, but bringing two-fold effects. The main one is the enhancement of the microstructural homogeneity by increasing the disorder degree. The other is weakening interatomic interactions as well as enabling the films more unstable due to the increasing system energy. The refractory high-entropy films can be promising candidates for high temperature, high hardness, and wearresistance applications, e.g., high-temperature-bearing structures, heat-protection systems, diffusion barriers, and film resistors.

Automated summary

In this study, a series of high-entropy alloy films were prepared by radio frequency magnetron sputtering, and systematic investigations were conducted on their microstructure, mechanical properties, and resistivity-temperature behavior. The addition of V did not alter the crystal structure of the films, but enhanced their homogeneity and instability.