Suresh Thapa scite author profile

Oxide two-dimensional electron gases (2DEGs) promise high charge carrier concentrations and low-loss electronic transport in semiconductors such as BaSnO 3 (BSO). ACBN0 computations for BSO/SrNbO 3 (SNO) interfaces show Nb-4d electron injection into extended Sn-5s electronic states. The conduction band minimum consists of Sn-5s states ∼1.2 eV below the Fermi level for intermediate thickness 6-unit cell BSO/6unit cell SNO superlattices, corresponding to an electron density in BSO of ∼10 21 cm −3 . Experimental studies of analogous BSO/SNO interfaces grown by molecular beam epitaxy confirm significant charge transfer from SNO to BSO. In situ angle-resolved X-ray photoelectron spectroscopy studies show an electron density of ∼4 × 10 21 cm −3 . The consistency of theory and experiments show that BSO/SNO interfaces provide a novel materials platform for low loss electron transport in 2DEGs.

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Probing surfaces and interfaces in complex oxide films via in situ X-ray photoelectron spectroscopy

Thapa

Paudel

Blanchet

et al. 2021

Journal of Materials Research

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Emergent behavior at oxide interfaces has driven research in complex oxide films for the past 20 years. Interfaces have been engineered for applications in spintronics, topological quantum computing, and high-speed electronics with properties not observed in bulk materials. Advances in synthesis have made the growth of these interfaces possible, while X-ray photoelectron spectroscopy (XPS) studies have often explained the observed interfacial phenomena. This review discusses leading recent research, focusing on key results and the XPS studies that enabled them. We describe how the in situ integration of synthesis and spectroscopy improves the growth process and accelerates scientific discovery. Specific techniques include determination of interfacial intermixing, valence band alignment, and interfacial charge transfer. A recurring theme is the role that atmospheric exposure plays on material properties, which we highlight in several material systems. We demonstrate how synchrotron studies have answered questions that are impossible in lab-based systems and how to improve such experiments in the future.

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Surface stability of SrNbO3+δ grown by hybrid molecular beam epitaxy

Thapa

Provence

Gemperline

et al. 2022

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4d transition metal oxides have emerged as promising materials for numerous applications including high mobility electronics. SrNbO3 is one such candidate material, serving as a good donor material in interfacial oxide systems and exhibiting high electron mobility in ultrathin films. However, its synthesis is challenging due to the metastable nature of the d1 Nb4+ cation and the limitations in the delivery of refractory Nb. To date, films have been grown primarily by pulsed laser deposition (PLD), but development of a means to grow and stabilize the material via molecular beam epitaxy (MBE) would enable studies of interfacial phenomena and multilayer structures that may be challenging by PLD. To that end, SrNbO3 thin films were grown using hybrid MBE for the first time using a tris(diethylamido)(tert-butylimido) niobium precursor for Nb and an elemental Sr source on GdScO3 substrates. Varying thicknesses of insulating SrHfO3 capping layers were deposited using a hafnium tert-butoxide precursor for Hf on top of SrNbO3 films to preserve the metastable surface. Grown films were transferred in vacuo for x-ray photoelectron spectroscopy to quantify elemental composition, density of states at the Fermi energy, and Nb oxidation state. Ex situ studies by x-ray absorption near edge spectroscopy and scanning transmission electron microscopy illustrate that the SrHfO3 capping plays an important role in preserving the crystalline quality of the material and the Nb 4d1 metastable charge state under atmospheric conditions.

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Probing surfaces and interfaces in complex oxide films via in situ X-ray photoelectron spectroscopy

et al. 2020

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Suresh Thapa

Machine learning analysis of perovskite oxides grown by molecular beam epitaxy

High Mobility Two-Dimensional Electron Gas at the BaSnO₃/SrNbO₃ Interface

Probing surfaces and interfaces in complex oxide films via in situ X-ray photoelectron spectroscopy

Surface stability of SrNbO3+δ grown by hybrid molecular beam epitaxy

Probing surfaces and interfaces in complex oxide films via in situ X-ray photoelectron spectroscopy

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About

Suresh Thapa

Machine learning analysis of perovskite oxides grown by molecular beam epitaxy

High Mobility Two-Dimensional Electron Gas at the BaSnO3/SrNbO3 Interface

Probing surfaces and interfaces in complex oxide films via in situ X-ray photoelectron spectroscopy

Surface stability of SrNbO3+δ grown by hybrid molecular beam epitaxy

Probing surfaces and interfaces in complex oxide films via in situ X-ray photoelectron spectroscopy

Contact Info

Product

Resources

About

High Mobility Two-Dimensional Electron Gas at the BaSnO₃/SrNbO₃ Interface