Researchers from The Grainger College of Engineering at the University of Illinois Urbana-Champaign have developed the first magnetic multipole-based micromagnetic model for antiferromagnets. Published in Applied Physics Reviews, their generalized framework provides a theoretical and computational foundation for designing future spintronic devices made with antiferromagnetic materials.
Unlike traditional electronics, which rely on an electron’s charge, spin electronics harnesses an electron’s magnetic orientation (spin). In recent years, materials science researchers have identified antiferromagnets as a promising material for future spintronic devices because of their ultrafast spin dynamics and stability under external magnetic fields.
But before these materials can be implemented in practical devices, researchers need robust models that decipher their complex, nonuniform movements. Although micromagnetic simulations have been widely used to study spin dynamics in ferromagnets, a comparable framework had yet to be fully established for antiferromagnets, whose spin structure is more difficult to control. However, some types of antiferromagnets—such as noncollinear antiferromagnets—have a unique rotating structure that is more easily manipulated.
