Ferroelectricity in antiferromagnetic wurtzite nitrides

Jan 1, 2026·
Sara M. Baksa
Linding Yuan
Linding Yuan
,
Stephen D. Wilson
,
James M. Rondinelli
· 0 min read
Abstract
Wurtzite-type nitrides have recently emerged as promising candidates for ferroelectric applications, yet their magnetic counterparts remain largely unexplored. Here, we establish MnSiN₂ and MnGeN₂ as aristotypes of a new multiferroic wurtzite family that simultaneously exhibits ferroelectricity and antiferromagnetism. These Mn(II)-based nitrides crystallize in polar structures and display robust G-type antiferromagnetism at room temperature. First-principles calculations reveal that nonmagnetic analogs incorporating Zn and Mg possess high polarization reversal barriers (0.735 and 0.683 eV per formula unit) and wide band gaps (4.0 and 4.8 eV), making them ideal ferroelectric candidates. In contrast, MnSiN₂ and MnGeN₂ exhibit strong antiferromagnetic exchange interactions (5–9 meV per Mn site) and moderate band gaps (1.6 and 1.0 eV), with reversal barriers of 0.963 and 0.460 eV per formula unit, respectively. Despite their limited magnetoelectric coupling, we show this family of Type-1 multiferroics exhibits altermagnetic spin splitting which reverses sign upon polarization switching. By strategically substituting alkaline-earth metals, we engineer multiple materials with coexisting switchable polarization, spin texture, and magnetic order. These findings open new avenues for the design of nitride-based altermagnetic multiferroics, offering a platform for integrated antiferromagnetic spintronic devices.
Type
Publication
Advanced Functional Materials e25545 (2026)
publications
Linding Yuan
Authors

I develop predictive theories of condensed matter materials and propose them for experimentalists to make. My work pairs first-principles calculations with symmetry analysis to discover new classes of materials with interesting electronic and magnetic properties. Specific material class of interests include semicondcutors and ferroic materials. My recent interest extends to integrating these methods into agentic workflows to accelerate materials discovery.

I moved to Evanston in May 2023 to join the Rondinelli Group at Northwestern University as a research associate.