Litcius/Paper detail

Piezoelectric effect and polarization switching in Al1−<i>x</i>Sc<i>x</i>N

Haochen Wang, Nicholas Adamski, Sai Mu, Chris G. Van de Walle

2021Journal of Applied Physics72 citationsDOIOpen Access PDF

Abstract

Aluminum nitride is piezoelectric and exhibits spontaneous polarization along the c axis, but the polarization cannot be switched by applying an electric field. Adding Sc to AlN enhances the piezoelectric properties and can make the alloy ferroelectric. We perform a detailed first-principles analysis of spontaneous and piezoelectric polarization. Comparisons between explicit supercell calculations show that the virtual crystal approximation produces accurate results for polarization but falls short in describing the phase stability of the alloy. We relate the behavior of the piezoelectric constant e33 to the microscopic behavior of the internal displacement parameter u, finding that the internal-strain contribution dominates in the Sc-induced enhancement. The value of u increases with scandium concentration, bringing the alloy locally closer to a layered hexagonal structure. Our approach allows us to calculate the ferroelectric switching barrier, which we analyze as a function of Sc concentration and temperature based on the Ginzburg–Landau theory.

Topics & Concepts

PiezoelectricityMaterials sciencePolarization (electrochemistry)FerroelectricityElectric displacement fieldCondensed matter physicsScandiumAlloyPiezoelectric coefficientInduced polarizationWide-bandgap semiconductorHexagonal crystal systemOptoelectronicsNitrideDisplacement (psychology)Polarization densityPhase (matter)Switching timeSingle crystalAcoustic Wave Resonator TechnologiesFerroelectric and Piezoelectric MaterialsGaN-based semiconductor devices and materials
Piezoelectric effect and polarization switching in Al1−<i>x</i>Sc<i>x</i>N | Litcius