TY - JOUR
T1 - La2 O3Mn2Se2
T2 - A correlated insulating layered d -wave altermagnet
AU - Wei, Chao Chun
AU - Li, Xiaoyin
AU - Hatt, Sabrina
AU - Huai, Xudong
AU - Liu, Jue
AU - Singh, Birender
AU - Kim, Kyung Mo
AU - Fernandes, Rafael M.
AU - Cardon, Paul
AU - Zhao, Liuyan
AU - Tran, Thao T.
AU - Frandsen, Benjamin M.
AU - Burch, Kenneth S.
AU - Liu, Feng
AU - Ji, Huiwen
N1 - ACKNOWLEDGMENTS We thank I. Mazin for the fruitful discussions. C.-C.W. and H.J. are supported by an NSF Career Grant No. 2145832. X.L. and F.L. acknowledge financial support from the DOE-BES (Grant No. DE-FG02-04ER46148). Computational resources for this work were supported by CHPC of the University of Utah and the DOE-NERSC. The atomic and magnetic pair distribution function analysis performed by S.R.H. and B.A.F. was supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences (DOE-BES) through Award No. DE-SC0021134. The neutron scattering experiments used resources at the Spallation Neutron Source, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. X.H. and T.T.T. thank the NSF (Awards No. NSF-OIA-2227933 and No. NSF-DMR-2338014) and the Arnold and Mabel Backman Foundation (2023 BYI Grant) for the support. The Air Force Office of Scientific Research supported R.M.F. (phenomenological model) under Award No. FA9550-21-1\u20130423 as well as B.S., K.M.K., and K.S.B. (Raman measurements and analysis) under Award No. FA9550-24-1\u20130110. L.Z. acknowledges the support by the NSF CAREER Grant No. DMR-174774 and Alfred P. Sloan Foundation.
We thank I. Mazin for the fruitful discussions. C.-C.W. and H.J. are supported by an NSF Career Grant No. 2145832. X.L. and F.L. acknowledge financial support from the DOE-BES (Grant No. DE-FG02-04ER46148). Computational resources for this work were supported by CHPC of the University of Utah and the DOE-NERSC. The atomic and magnetic pair distribution function analysis performed by S.R.H. and B.A.F. was supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences (DOE-BES) through Award No. DE-SC0021134. The neutron scattering experiments used resources at the Spallation Neutron Source, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. X.H. and T.T.T. thank the NSF (Awards No. NSF-OIA-2227933 and No. NSF-DMR-2338014) and the Arnold and Mabel Backman Foundation (2023 BYI Grant) for the support. The Air Force Office of Scientific Research supported R.M.F. (phenomenological model) under Award No. FA9550-21-1\u20130423 as well as B.S., K.M.K., and K.S.B. (Raman measurements and analysis) under Award No. FA9550-24-1\u20130110. L.Z. acknowledges the support by the NSF CAREER Grant No. DMR-174774 and Alfred P. Sloan Foundation.
PY - 2025/2
Y1 - 2025/2
N2 - Altermagnets represent a new class of magnetic phases without net magnetization, invariant under a combination of rotation and time reversal. Unlike conventional collinear antiferromagnets (AFM), altermagnets could lead to new correlated states and important material properties deriving from their nonrelativistic spin-split band structure. Indeed, they serve as the magnetic analogue of unconventional superconductors and can yield spin-polarized electrical currents in the absence of external magnetic fields, making them promising candidates for next-generation spintronics. Here, we report altermagnetism in the correlated insulator, magnetically ordered tetragonal oxychalcogenide, La2O3Mn2Se2. Symmetry analysis reveals a dx2-y2-wave-like spin-momentum locking arising from the Mn2O Lieb lattice, supported by density functional theory (DFT) calculations. Magnetic measurements confirm the AFM transition below ∼166K while neutron pair distribution function analysis reveals a 2D short-range magnetic order that persists above the Néel temperature. Single crystals are grown and characterized using x-ray diffraction, optical and electron microscopy, and micro-Raman spectroscopy to confirm the crystal structure, stoichiometry, and uniformity. Our findings establish La2O3Mn2Se2 as a model altermagnetic system realized on a Lieb lattice.
AB - Altermagnets represent a new class of magnetic phases without net magnetization, invariant under a combination of rotation and time reversal. Unlike conventional collinear antiferromagnets (AFM), altermagnets could lead to new correlated states and important material properties deriving from their nonrelativistic spin-split band structure. Indeed, they serve as the magnetic analogue of unconventional superconductors and can yield spin-polarized electrical currents in the absence of external magnetic fields, making them promising candidates for next-generation spintronics. Here, we report altermagnetism in the correlated insulator, magnetically ordered tetragonal oxychalcogenide, La2O3Mn2Se2. Symmetry analysis reveals a dx2-y2-wave-like spin-momentum locking arising from the Mn2O Lieb lattice, supported by density functional theory (DFT) calculations. Magnetic measurements confirm the AFM transition below ∼166K while neutron pair distribution function analysis reveals a 2D short-range magnetic order that persists above the Néel temperature. Single crystals are grown and characterized using x-ray diffraction, optical and electron microscopy, and micro-Raman spectroscopy to confirm the crystal structure, stoichiometry, and uniformity. Our findings establish La2O3Mn2Se2 as a model altermagnetic system realized on a Lieb lattice.
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U2 - 10.1103/PhysRevMaterials.9.024402
DO - 10.1103/PhysRevMaterials.9.024402
M3 - Article
AN - SCOPUS:85217759540
SN - 2475-9953
VL - 9
JO - Physical Review Materials
JF - Physical Review Materials
IS - 2
M1 - 024402
ER -