Distinguishing apparent and hidden altermagnetism via uniaxial strain in CsV2Te2O-family
Abstract
The hidden altermagnetism has been theoretically proposed and then experimentally confirmed in metal Cs1-δV2Te2O, which exhibits two nearly degenerate ground-state magnetic configurations (C-type and G-type) corresponding respectively to apparent and hidden altermagnetism. Here, we propose that in-plane uniaxial strain can be utilized to distinguish apparent and hidden altermagnetism. Under uniaxial strain, apparent altermagnetism exhibits an obvious net magnetic moment, whereas hidden altermagnetism maintains zero net magnetic moment. The magnetic moment induced by uniaxial strain here, namely the piezomagnetic effect, differs from that in semiconductors, where strain must be applied first followed by carrier doping to generate net magnetism. First-principles calculations verify our proposal, revealing that the magnetic moment induced by uniaxial strain in C-type antiferromagnetic CsV2Te2O is much larger than that in the previously studied altermagnetic semiconductors. Furthermore, we also investigate the electronic state transitions of semiconductors featuring a crystal structure analogous to CsV2Te2O under uniaxial strain, and verify our proposal in specific material via first-principles calculations. Our work provides an experimentally feasible strategy to distinguish apparent and hidden altermagnetism in material Cs1-δV2Te2O, and extends the physical implication of the piezomagnetic effect, which can be directly verified in experimentally synthesizable KV2Se2O and Rb1-δV2Te2O.
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