Nitrogen-Vacancy-Mediated Magnetism in Sputtered GdN Thin Films

TL;DR

This study demonstrates that nitrogen vacancies in sputtered GdN thin films induce defect-mediated ferromagnetism, with controlled defect levels enhancing magnetic properties and offering pathways for spintronics device optimization.

Contribution

It provides a systematic investigation of how nitrogen-vacancy defects influence the magnetic properties of sputtered GdN thin films, linking structural defects to ferromagnetism.

Findings

Nitrogen vacancies correlate with increased Curie temperature.

GdN films exhibit soft ferromagnetic behavior with Tc up to 82 K.

Defect engineering enhances magnetic properties for spintronics.

Abstract

Among rare-earth nitrides (RENs), gadolinium nitride (GdN) stands out as a promising material for spintronics owing to its distinctive combination of semiconducting behavior, strong exchange interactions, and intrinsically soft ferromagnetism. Its relatively high Curie temperature and large saturation magnetization make it an attractive candidate for device concepts such as non-volatile memory elements and spin-based transistors, motivating efforts toward low-cost, uniform, and compositionally controlled thin-film growth. In this work, we deposited GdN thin films on SiO2/AlN substrates using DC sputtering under reactive nitridation conditions, with thicknesses varying from 18 to 180 nm, and systematically investigated their structural and magnetic properties. The films exhibit soft ferromagnetic ordering, characterized by a coercive field of approximately 200 Oe and a Curie temperature (Tc) near 70 K. Structural analysis reveals lattice distortions and local strain associated with nitrogen-vacancy defects, whose concentration varies with film thickness. Our theoretical studies establish a direct correlation between the observed Raman modes of the GdN lattice and the reduced magnetization induced by nitrogen vacancies. These vacancies give rise to defect-mediated ferromagnetism, leading to a measurable enhancement of Tc from 68 K to 82 K across the studied thickness range. The observed magnetic behavior is well described by the bound magnetic polaron (BMP) model, confirming that nitrogen vacancies are key contributors to ferromagnetic ordering while preserving the soft-magnetic character intrinsic to GdN. This study underscores the pivotal role of defect engineering in optimizing GdN thin films for spintronics applications.