An analysis of the symmetry evolution and domain structure in RbFe(MoO₄)₂ near its ferroaxial phase transition

The physics of frustrated magnets can be modeled as a two-dimensional triangle lattice antiferromagnet (2D TLA). One of the first such 2D TLA candidates discovered was RbFe(MoO₄)₂. Interest in this material has recently been renewed due to the discovery of ferroelectricity in the vicinity of antiferromagnetism (AFM) around 3.8K, which leads to a multiferroic state. The magnetic structure of RbFe(MoO₄)₂ has a structural phase transition at temperature T_C≈190K which leads to a ferroaxial magnetic structure, but the nature of this ferroaxial phase transition and its domain distribution are not yet know. This is important because current understanding of the ferroelectricity in RbFe(MoO₄)₂ depends on the AFM order hosted on the ferroaxial crystal lattice. In this talk, I present an analysis using an ultrafast rotation anisotropy and second harmonic generation (RA-SHG) experiment to investigate the symmetry evolution around T_C and wide-field SHG imaging to resolve the domain distribution of the ferroaxial structure order.