What does this research mean for the field?

Removing hydrogen impurities from MgZnO significantly increases the Schottky barrier height by up to 240 meV and enhances electronic properties for improved device performance. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The aim is to understand how hydrogen impurities affect the electronic performance of MgZnO-based devices.

February 28, 2026Open Access

Toward superior MgZnO tunnel and Schottky devices: The role of hydrogen impurity removal

Key Points

The aim is to understand how hydrogen impurities affect the electronic performance of MgZnO-based devices.
Epitaxial growth of MgZnO thin films on Pt/CoPt electrodes via oxygen plasma-assisted molecular beam epitaxy.
Quantification of hydrogen's impact on electronic properties at metal/oxide interfaces.
Analysis using the Brinkman–Dynes–Rowell model to assess tunnel junction characteristics.
Removal of hydrogen increases Schottky barrier height by up to 237 meV and enhances tunneling barrier height by about 40 meV.
Thermionic leakage is reduced by five orders of magnitude after hydrogen removal.
A hydrogen dipole model links the 240 meV shift in Schottky barrier height to an observed hydrogen concentration of ∼ 1.7 × 10^19 cm − 3.

Abstract

Controlling hydrogen incorporation in wide-bandgap semiconductors is increasingly recognized as a key requirement for achieving reliable performance in next-generation electronic, optoelectronic, and spintronic devices. In wurtzite MgZnO, hydrogen acts simultaneously as an unintentional shallow donor and an interface-active species, strongly modifying band alignment, barrier formation, and Mg incorporation efficiency. In this work, we report the epitaxial growth of (0001)-oriented single-phase wurtzite Mg x Zn 1 − x O thin films on Pt/Co 0.30 Pt 0.70 (111) electrodes using oxygen plasma-assisted molecular beam epitaxy. We systematically quantify the impact of hydrogen residues on the electronic properties of the resulting metal/oxide interfaces. Analysis of MgZnO-based tunnel junctions using the Brinkman–Dynes–Rowell model, together with back-to-back Schottky diode characteristics, reveals that residual hydrogen significantly reduces both the tunneling barrier and the Schottky barrier heights by ∼ 40 meV and ∼ 240 meV, respectively, for an existing effective hydrogen concentration on the order of 1 0 19 cm − 3 . Removing hydrogen suppresses the unintentional n -type conductivity, enhances Mg incorporation in the initial growth layers, and restores a higher interfacial potential barrier. These findings demonstrate that the Pt/CoPt/MgZnO hetero-structure is highly sensitive to hydrogen-related defects, and that precise hydrogen control is essential for engineering predictable band alignment and transport characteristics. The resulting tunability positions MgZnO on ferromagnetic CoPt as a promising platform for emerging opto-spintronics applications, including electrically driven spin-LEDs and spin-controlled ultraviolet photonic devices. • Hydrogen removal increases SBH at CoPt/MgZnO and Pt/MgZnO by up to 237 meV. • Thermionic leakage at –2 V is suppressed by five orders of magnitude after H 2 removal. • Tunneling barrier height and width increase by ∼ 40 meV and ∼ 1.5 nm, respectively. • Hydrogen dipole model links 240 meV SBH shift to ∼ 1.7 × 1 0 19 cm − 3 H concentration. • Epitaxial MgZnO forms a bilayer structure with tunable Mg content and no ZnO-like interlayer.

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