Spin-orbit enabled unconventional Stoner magnetism

The Stoner instability remains a cornerstone for understanding metallic ferromagnets. This magnetic instability captures the interplay of Coulomb repulsion, Pauli exclusion, and two-fold fermionic spin degeneracy. In materials with spin-orbit coupling, fermionic spin is generalized to a two-fold degenerate pseudospin. Here we identify a new fermionic pseudospin with a symmetry that does not allow it to couple to a Zeeman field. This spinless pseudospin exists in five non-symmorphic space groups and appears at the Brillouin zone (BZ) boundary. In the presence of Coulomb repulsion, this spinless pseudopsin gives rise to metallic Stoner instabilities into magnetic states that are not usual ferromagnets. While these spinless pseudopsin ferromagnets break time-reversal symmetry, they have a vanishing magnetization and are generally non-collinear. The non-collinear magnetization enables a scalar spin chirality driven Berry curvature. In addition, much like altermagnets, these pseudospin ferromagnets exhibit energy band spin-splittings that vanish by symmetry along lines in the BZ, allowing for drumhead surfaces states. We further discuss candidate materials.