npj Computational Materials (Feb 2025)
Realizing giant ferroelectricity in stable wz-Al1 − x B x N alloys by controlling the microstructure and elastic constant
Abstract
Abstract The emerged wurtzite (wz) Al1−x B x N alloy has drawn increasing attention due to its superior ferroelectricity and excellent compatibility with microelectronics. We find that the stability and ferroelectric switching pathways of wz-Al1−x B x N alloys are affected by the orbital contribution, covalent bond strength, and elastic constant C 14. As the concentration of B increases, the internal parameter u decreases while the elastic constant C14 increases, leading to an increase in spontaneous polarization and a decrease in the polarization switching barrier. The spontaneous polarization, polarization switching barrier, and band gap of wz-Al1−x B x N alloy can be further improved through the application of strain in a specific direction, resulting in a giant ferroelectricity. Additionally, the phase transformation of the wz-Al1−x B x N alloy induced by the increasing B composition can be regarded as a sequential process involving shrinkage, rotation, and deformation of tetrahedron. These findings give a deep understanding of the ferroelectric wz-Al1−x B x N alloy, and provide a guideline for designing a high-performance ferroelectric wz-Al1−x B x N alloy.
