Transition from antiferromagnetism to altermagnetism: symmetry breaking theory

Abstract: Altermagnetism, a recently proposed magnetic phase, is distinguished by the antiferromagnetic coupling of local magnetic moments and the breaking of time-reversal symmetry. Currently, the transition from conventional antiferromagnetism to altermagnetism is not well understood. In this letter, we introduce a comprehensive symmetry-breaking theory to elucidate this transition. Our approach involves analyzing magnetic point groups and their subgroups to identify potential pathways for the phase transition from collinear antiferromagnetism to altermagnetism. According to our theory, breaking inversion symmetry is crucial for this transition. We discovered that applying an external electric field is a highly effective method to realize altermagnetic phase, as demonstrated by first-principles calculations on the two-dimensional antiferromagnetic material MoTe. Furthermore, we show that the electronic spin polarization and spin-dependent transport can be significantly modulated by the applied vertical electric field. Our study not only sheds light on the magnetic phase transition from antiferromagnetic to altermagnetic materials but also presents a practical approach to control the charge-spin conversion ratio using an vertical electric field.