• Kapaklis, Vassilios
• Spode, Lennart
• Ravensburg, Anna Lena
• Svedlindh, Peter
• Pálsson, Gunnar K.
• Brucas, Rimantas
• Music, Denis

Abstract

The fundamental understanding of the metal/ceramic interface is of crucial importance to diverse fields such as spintronics, energy conversion and storage devices, as well as fusion reactors. The conditions whereby epitaxy is achieved are commonly believed to be mostly governed by misfit strain. We report on a systematic investigation of growth and interface structure of single crystalline tungsten thin films on two different metal oxide substrates, Al$_{2}$O$_{3}$ ($11{2}0$) and MgO ($001$). X-ray scattering techniques and high-resolution transmission electron microscopy have been used to assess the overall epitaxial quality of the tungsten layers. We demonstrate that despite the significant mismatch for both substrates, enhanced crystal quality is observed for tungsten grown on the sapphire substrates. This is promoted by stronger adhesion and chemical bonding with sapphire compared to magnesium oxide, along with the restructuring of the tungsten layers close to the sapphire/tungsten interface. The latter is supported by ab initio calculations using density functional theory. Finally, we demonstrate the growth of magnetic heterostructures consisting of high-quality tungsten layers in combination with ferromagnetic CoFe layers, which are relevant for spintronic applications.

Topics

• density
• impedance spectroscopy
• theory
• thin film
• Magnesium
• Magnesium
• transmission electron microscopy
• density functional theory
• tungsten
• X-ray scattering
• magnesium oxide