Ab-initio elastic tensor of cubic Ti0.5Al0.5N alloy: the dependence of the elastic constants on the size and shape of the supercell model

Abstract

In this study we discuss the performance of approximate SQS supercell models in describing the cubic elastic properties of B1 (rocksalt) Ti0.5Al0.5N alloy by using a symmetry based projection technique. We show on the example of Ti0.5Al0.5N alloy, that this projection technique can be used to align the differently shaped and sized SQS structures for a comparison in modeling elasticity. Moreover, we focus to accurately determine the cubic elastic constants and Zener's type elastic anisotropy of Ti0.5Al0.5N. Our best supercell model, that captures accurately both the randomness and cubic elastic symmetry, results in C11=447 GPa, C12=158 GPa and C44=203 GPa with 3% of error and A=1.40 for Zener's elastic anisotropy with 6% of error. In addition, we establish the general importance of selecting proper approximate SQS supercells with symmetry arguments to reliably model elasticity of alloys. In general, we suggest the calculation of nine elastic tensor elements - C11, C22, C33, C12, C13, C23, C44, C55 and C66, to evaluate and analyze the performance of SQS supercells in predicting elasticity of cubic alloys via projecting out the closest cubic approximate of the elastic tensor. The here described methodology is general enough to be applied in discussing elasticity of substitutional alloys with any symmetry and at arbitrary composition.