Topological piezomagnetic effect in two-dimensional Dirac quadrupole altermagnets
Abstract
Altermagnets provide a natural platform for studying and exploiting piezomagnetism. In this paper, we introduce a class of insulating altermagnets in two dimensions (2D) referred to as Dirac quadrupole altermagnets, and show based on microscopic minimal models that the orbital piezomagnetic polarizability of such altermagnets has a topological contribution described by topological response theory. The essential low-energy electronic structure of Dirac quadrupole altermagnets can be understood from a gapless parent phase (i.e., the Dirac quadrupole semimetal), which has important implications for their response to external fields. Focusing on the strain-induced response, here we demonstrate that the topological piezomagnetic effect is a consequence of the way in which strain affects the Dirac points forming a quadrupole. We consider two microscopic models: a spinless two-band model describing a band inversion of and states, and a Lieb lattice model with collinear N\'eel order. The latter is a prototypical minimal model for altermagnetism in 2D and is realized in a number of recently proposed material compounds, which are discussed.
Cite
@article{arxiv.2602.05894,
title = {Topological piezomagnetic effect in two-dimensional Dirac quadrupole altermagnets},
author = {H. Radhakrishnan and B. Bell and C. Ortix and J. W. F. Venderbos},
journal= {arXiv preprint arXiv:2602.05894},
year = {2026}
}
Comments
v2, 5 pages, 3 figures; Suppl.: 5 pages, 1 figure