Litcius/Paper detail

Engineering Strain and Texture in Ferroelectric Scandium-Doped Aluminium Nitride

S. R. C. McMitchell, A. Walke, Kaustuv Banerjee, S. Mertens, Xiaoyu Piao, Ming Mao, Kostantine Katcko, G. Vellianitis, Mark van Dal, Yu-Ming Lin, G. Van den bosch, Romain Delhougne, Gouri Sankar Kar

2023ACS Applied Electronic Materials21 citationsDOI

Abstract

Materials and interfacial engineering yielded ferroelectricity in Al 1– x Sc x N films of 15 nm thickness for the first time. Bottom electrodes were explored and selected for optimal properties through modification of the strain state and thus the texture in the films. Pt bottom interfaces were shown to be the best for the widest doping window of Sc in the structure and the lowest leakage. Mo bottom interfaces promoted mixed texture in the films, which led to a reduced breakdown E-field and a reduced doping window. Top electrode stacks were shown to modify strain state and effect leakage, enabling full interfacial engineering of this material. Here, Mo top electrode interfaces caused a reduction of the coercive electric field, thus allowing strain engineering of this material and opening the door to application in memory devices.

Topics & Concepts

Materials scienceFerroelectricityScandiumDopingStrain engineeringElectrodeLeakage (economics)Texture (cosmology)Composite materialAluminiumNitrideOptoelectronicsMetallurgyDielectricSiliconComputer scienceLayer (electronics)Physical chemistryArtificial intelligenceEconomicsMacroeconomicsChemistryImage (mathematics)Acoustic Wave Resonator TechnologiesFerroelectric and Piezoelectric MaterialsMetal and Thin Film Mechanics
Engineering Strain and Texture in Ferroelectric Scandium-Doped Aluminium Nitride | Litcius