Compression properties and impact energy release characteristics of TiZrNbV high-entropy alloy

To explore the potential of high-entropy alloys (HEAs) as energetic structural materials (ESMs), the compression behaviors and impact energy release characteristics of TiZrNbV HEA were investigated. Mechanical experiments at strain rates from 1 x 10(-3) s(-1) to 1 x 10(4) s(-1) showed that TiZrNbV HEA exhibits clear dynamic brittle fracture behavior under dynamic compression loading, which is diametrically opposite to its behavior under quasi-static compression loading. A Johnson-Cook constitutive model for TiZrNbV HEA was obtained by fitting the experimental data, which demonstrated an apparent strain rate effect. Numerical simulation and microstructure results revealed the role of an adiabatic shear band (ASB) in the brittle fracture. The crack profiles that evolved from the ASB exhibited the typical characteristic for high temperatures. The degree and rate of the chemical reaction and recycled products of direct ballistic tests indicated that severe oxidation reactions induced by the high-temperature profiles resulted in chemical energy release under impact loading. The relationship between the material microstructure and macromechanical behavior of TiZrNbV HEA, which is important in the use of HEAs as ESMs, was revealed in this study through mechanical and material methods and finite element numerical simulation.

Automated summary

The study investigated the compression behaviors and impact energy release characteristics of TiZrNbV HEA, finding that it exhibits dynamic brittle fracture behavior under dynamic compression loading, in contrast to its behavior under quasi-static compression. A Johnson-Cook constitutive model for TiZrNbV HEA was obtained by fitting the experimental data, demonstrating an apparent strain rate effect.