Classification of Magnetism and Altermagnetism in Quasicrystals (2508.15702v1)

Abstract: Altermagnetism, an unconventional magnetic phase characterized by zero net magnetism and a spin-split electronic band, has been studied exclusively in conventional crystalline materials. In this work, we extend the theoretical framework of altermagnetism to quasicrystals (QCs), which lack translational symmetry. We classify magnetic phases in 2D QCs with $n$-fold rotational symmetry without spin-orbit coupling, by using the irreducible representation (IRRP) of the $D_n$ point group. Based on symmetry analysis, we propose the conjecture that magnetic phases corresponding to 1D non-identity IRRPs are generally altermagnetic, with the exception of those possessing parity-time symmetry. To verify our conjecture, we take the Hubbard model as an example and develop a systematic approach to determine the magnetic pattern in the QC, which effectively avoids getting trapped at local energy minima. Consequently, our tests for the Hubbard model on various QCs with different symmetries are unexceptionally consistent with our proposal. Our work highlights the QC as a platform where the altermagnetism is common among magnetic phases.