Computational thermo-elastic homogenization of Al2O3 and SiC polycrystals by DR-BEM

The presented data have been generated employing a grain-scale framework for thermo-elastic analysis and computational homogenization of polycrystalline materials. In the developed framework: 1) The morphology of crystal aggregates is represented employing Voronoi tessellations generated through the open source package NEPER ( https://neper.info/ ). 2) The behaviour of individual grains is modelled using an integral representation for fully anisotropic thermo-elasticity, numerically addressed through a dual reciprocity boundary element method (DR-BEM). 3) The integrity of the aggregate is restored through intergranular thermoelastic continuity conditions. The framework has been tailored for computational thermo-elastic homogenization of polycrystalline materials and it has been applied to the statistical computational homogenization of SiC and Al2O3 polycrystals, whose data are presented here. Detailed information about the provided data and detailed steps access it are given below.