Symmetry Classification of Magnetic Orders and Emergence of Spin-Orbit Magnetism (2506.20739v1)

Abstract: Magnetism, a fundamental concept predating condensed matter physics, has achieved significant advancements in recent decades, driven by its potential for next-generation storage devices. Meanwhile, the classification of magnetic orders, even for the most fundamental concepts like ferromagnetism (FM) and antiferromagnetism (AFM), has encountered unprecedented challenges since the discovery of unconventional magnets and advancements in antiferromagnetic spintronics. Here, we present a rigorous classification of magnetic order using state-of-the-art spin space group (SSG) theory. Based on whether the net magnetic moment is constrained to zero by SSG, magnetic order is unambiguously dichotomized into FM (including ferrimagnetism) and AFM. Additionally, we classify AFM geometries into four categories -- primary, bi-color, spiral, and multi-axial -- based on periodic spin propagation beyond the symmetry operations of magnetic space groups. We then introduce a distinct magnetic phase, dubbed spin-orbit magnetism, characterized by its unique behavior involving the spin-orbit coupling (SOC) order parameter and SOC-driven phase transition. We further create an oriented SSG description, i.e., SSG with a fixed magnetic configuration, apply the framework to 2,065 experimentally validated magnetic materials in MAGNDATA database, and identify over 220 spin-orbit magnets with distinct spin and orbital magnetization mechanisms. Implemented by the online program FINDSPINGROUP, our work establishes a universal symmetry standard for magnetic order classification, offering new understandings of unconventional magnets and broad applicability in spintronics and quantum material design.