Sliding ferroelectric metal with ferrimagnetism
Zhenzhou Guo, Shifeng Qian, Xiaodong Zhou, Wenhong Wang, Zhenxiang Cheng, Xiaotian Wang
Abstract
In this work, we develop a general strategy for constructing two-dimensional sliding ferroelectric ferrimagnetic metals from antiferromagnetic metallic bilayers, achieving triply-coupled switching in which the ferroelectric polarization, spin splitting, and net magnetic moment are simultaneously reversed via ferroelectric switching. As a prototype, we design a sliding bilayer ferroelectric metal with ferrimagnetic order based on Fe5GeTe2, a van der Waals ferromagnet near room temperature. The system undergoes a ferroelectric phase transition from a nonpolar antiferromagnetic phase to a ferroelectric ferrimagnetic phase driven by relative interlayer sliding. The breaking of in-plane mirror symmetry in the ferroelectric metallic states lifts the non-relativistic spin degeneracy present in the nonpolar phase, resulting in a sizable net magnetic moment. Moreover, the coexistence of metallic conductivity, ferroelectricity, and ferrimagnetism gives rise to pronounced sign-reversible transport responses near the Fermi level, all of which can be electrically modulated through ferroelectric switching. This work identifies the two-dimensional sliding ferroelectric metal with ferrimagnetism, enabling electric-field-driven triply-coupled switching with simultaneous reversal of the net magnetization, out-of-plane polarization, and spin splitting.