Spiral ground state against ferroelectricity in the frustrated magnet BiMnFe2O6

The spiral magnetic structure and underlying spin lattice of BiMnFe2O6 are investigated by low-temperature neutron powder diffraction and density functional theory band structure calculations. In spite of the random distribution of the Mn3+ and Fe3+ cations, this compound undergoes a transition into an incommensurate antiferromagnetically ordered state below TN ~ 220 K. The magnetic structure is characterized by the propagation vector k=[0,beta,0] with beta ~ 0.14 and the P22_12_11'(0 \beta 0)0s0s magnetic superspace symmetry. It comprises antiferromagnetic helixes propagating along the b-axis. The magnetic moments lie in the ac plane and rotate about pi*(1+beta) ~ 204.8 deg angle between the adjacent magnetic atoms along b. The spiral magnetic structure arises from the peculiar frustrated arrangement of exchange couplings in the ab plane. The antiferromagnetic coupling along the c-axis leads to the cancellation of electric polarization, and results in the lack of ferroelectricity in BiMnFe2O6.Comment: 11 pages, 8 figures, 8 table

Observation of a spontaneous anomalous Hall response in the Mn5Si3 d-wave altermagnet candidate

Phases with spontaneous time-reversal (T ) symmetry breaking are sought after for their anomalous physical properties, low-dissipation electronic and spin responses, and information-technology applications. Recently predicted altermagnetic phase features an unconventional and attractive combination of a strong T -symmetry breaking in the electronic structure and a zero or only weak-relativistic magnetization. In this work, we experimentally observe the anomalous Hall effect, a prominent representative of the T -symmetry breaking responses, in the absence of an external magnetic field in epitaxial thin-film Mn5Si3 with a vanishingly small net magnetic moment. By symmetry analysis and first-principles calculations we demonstrate that the unconventional d-wave altermagnetic phase is consistent with the experimental structural and magnetic characterization of the Mn5Si3 epilayers, and that the theoretical anomalous Hall conductivity generated by the phase is sizable, in agreement with experiment. An analogy with unconventional d-wave superconductivity suggests that our identification of a candidate of unconventional d-wave altermagnetism points towards a new chapter of research and applications of magnetic phases

Observation of a spontaneous anomalous Hall response in the Mn5Si3 d-wave altermagnet candidate

Phases with spontaneous time-reversal (T) symmetry breaking are sought after for their anomalous physical properties, low-dissipation electronic and spin responses, and information-technology applications. Recently predicted altermagnetic phase features an unconventional and attractive combination of a strong T-symmetry breaking in the electronic structure and a zero or only weak-relativistic magnetization. In this work, we experimentally observe the anomalous Hall effect, a prominent representative of the T-symmetry breaking responses, in the absence of an external magnetic field in epitaxial thin-film Mn5Si3 with a vanishingly small net magnetic moment. By symmetry analysis and first-principles calculations we demonstrate that the unconventional d-wave altermagnetic phase is consistent with the experimental structural and magnetic characterization of the Mn5Si3 epilayers, and that the theoretical anomalous Hall conductivity generated by the phase is sizable, in agreement with experiment. An analogy with unconventional d-wave superconductivity suggests that our identification of a candidate of unconventional d-wave altermagnetism points towards a new chapter of research and applications of magnetic phases

Macroscopic time reversal symmetry breaking arising from antiferromagnetic Zeeman effect

Time-reversal (T) symmetry breaking is a fundamental physics concept underpinning a broad science and technology area, including topological magnets, axion physics, dissipationless Hall currents, or spintronic memories. A central role in the field has been played by ferromagnets with spontaneously Zeeman-split bands and corresponding macroscopic T-symmetry breaking phenomena observable in the absence of an external magnetic field. In contrast, the Neel antiferromagnetism with anti-parallel atomic moments was not considered to generate the Zeeman splitting, leaving this abundant materials family outside of the focus of research of macroscopic T-symmetry breaking. Here, we discover a T-symmetry breaking mechanism in a compensated collinear antiferromagnet Mn5Si3, with a Zeeman splitting in the momentum space whose sign alternates across the electronic band structure. We identify the antiferromagnetic Zeeman effect using ab initio electronic structure calculations and from an analysis of spin-symmetries which were previously omitted in relativistic physics classifications of spin-splittings and topological quasiparticles. To experimentally demonstrate the macroscopic T-symmetry breaking in a Zeeman-split antiferromagnet, we measure the spontaneous Hall effect in Mn5Si3 epilayers exhibiting a negligible net magnetic moment. The experimental Hall conductivities are consistent with our ab initio calculations of the intrinsic disorder-independent contribution, proportional to the topological Berry curvature. Our study of the multi-sublattice antiferromagnet Mn5Si3 illustrates that a robust macroscopic T-symmetry breaking from the antiferromagnetic Zeeman effect is compatible with a unique set of material properties, including low atomic numbers, collinear magnetism with weak spin-decoherence, and vanishing net magnetization