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Hybrid molecular beam epitaxy of germanium-based oxides

Fengdeng Liu, Tristan K. Truttmann, Dooyong Lee, Bethany E. Matthews, Iflah Laraib, Anderson Janotti, Steven R. Spurgeon, Scott A. Chambers, Bharat Jalan

2022Communications Materials16 citationsDOIOpen Access PDF

Abstract

Abstract Germanium-based oxides such as rutile GeO 2 are garnering attention owing to their wide band gaps and the prospects of ambipolar doping for application in high-power devices. Here, we present the use of germanium tetraisopropoxide (GTIP), a metal-organic chemical precursor, as a source of germanium for the demonstration of hybrid molecular beam epitaxy for germanium-containing compounds. We use Sn 1- x Ge x O 2 and SrSn 1- x Ge x O 3 as model systems to demonstrate our synthesis method. A combination of high-resolution X-ray diffraction, scanning transmission electron microscopy, and X-ray photoelectron spectroscopy confirms the successful growth of epitaxial rutile Sn 1- x Ge x O 2 on TiO 2 (001) substrates up to x = 0.54 and coherent perovskite SrSn 1- x Ge x O 3 on GdScO 3 (110) substrates up to x = 0.16. Characterization and first-principles calculations corroborate that germanium occupies the tin site, as opposed to the strontium site. These findings confirm the viability of the GTIP precursor for the growth of germanium-containing oxides by hybrid molecular beam epitaxy, thus providing a promising route to high-quality perovskite germanate films.

Topics & Concepts

GermaniumMolecular beam epitaxyMaterials scienceEpitaxyTinX-ray photoelectron spectroscopyCrystallographyAnalytical Chemistry (journal)NanotechnologyOptoelectronicsChemistrySiliconMetallurgyPhysicsNuclear magnetic resonanceLayer (electronics)ChromatographyElectronic and Structural Properties of OxidesFerroelectric and Piezoelectric MaterialsPerovskite Materials and Applications