Giant momentum-dependent spin splitting in centrosymmetric low Z antiferromagnets
The energy vs. crystal momentum E(k) diagram for a solid (band structure) constitutes the road map for navigating its optical, magnetic, and transport properties. By selecting crystals with specific atom types, composition and symmetries, one could design a target band structure and thus desired pro...
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| Abstract | The energy vs. crystal momentum E(k) diagram for a solid (band structure) constitutes the road map for navigating its optical, magnetic, and transport properties. By selecting crystals with specific atom types, composition and symmetries, one could design a target band structure and thus desired properties. A particularly attractive outcome would be to design energy bands that are split into spin components with a momentum-dependent splitting, as envisioned by Pekar and Rashba [Zh. Eksperim. i Teor. Fiz. 47 (1964)], enabling spintronic application. The current paper provides "design principles" for wavevector dependent spin splitting (SS) of energy bands that parallels the traditional Dresselhaus and Rashba spin-orbit coupling (SOC) - induce splitting, but originates from a fundamentally different source -- antiferromagnetism. We identify a few generic AFM prototypes with distinct SS patterns using magnetic symmetry design principles. These tools allow also the identification of specific AFM compounds with SS belonging to different prototypes. A specific compound -- centrosymmetric tetragonal MnF2 -- is used via density functional band structure calculations to quantitatively illustrate one type of AFM SS. Unlike the traditional SOC-induced effects restricted to non-centrosymmetric crystals, we show that antiferromagnetic-induced spin splitting broadens the playing field to include even centrosymmetric compounds, and gives SS comparable in magnitude to the best known ('giant') SOC effects, even without SOC, and consequently does not rely on the often-unstable high atomic number elements required for high SOC. We envision that use of the current design principles to identify an optimal antiferromagnet with spin-split energy bands would be beneficial for efficient spin-charge conversion and spin orbit torque applications without the burden of requiring compounds containing heavy elements. |
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| AbstractList | Phys. Rev. B 102, 014422 (2020) The energy vs. crystal momentum E(k) diagram for a solid (band structure)
constitutes the road map for navigating its optical, magnetic, and transport
properties. By selecting crystals with specific atom types, composition and
symmetries, one could design a target band structure and thus desired
properties. A particularly attractive outcome would be to design energy bands
that are split into spin components with a momentum-dependent splitting, as
envisioned by Pekar and Rashba [Zh. Eksperim. i Teor. Fiz. 47 (1964)], enabling
spintronic application. The current paper provides "design principles" for
wavevector dependent spin splitting (SS) of energy bands that parallels the
traditional Dresselhaus and Rashba spin-orbit coupling (SOC) - induce
splitting, but originates from a fundamentally different source --
antiferromagnetism. We identify a few generic AFM prototypes with distinct SS
patterns using magnetic symmetry design principles. These tools allow also the
identification of specific AFM compounds with SS belonging to different
prototypes. A specific compound -- centrosymmetric tetragonal MnF2 -- is used
via density functional band structure calculations to quantitatively illustrate
one type of AFM SS. Unlike the traditional SOC-induced effects restricted to
non-centrosymmetric crystals, we show that antiferromagnetic-induced spin
splitting broadens the playing field to include even centrosymmetric compounds,
and gives SS comparable in magnitude to the best known ('giant') SOC effects,
even without SOC, and consequently does not rely on the often-unstable high
atomic number elements required for high SOC. We envision that use of the
current design principles to identify an optimal antiferromagnet with
spin-split energy bands would be beneficial for efficient spin-charge
conversion and spin orbit torque applications without the burden of requiring
compounds containing heavy elements. The energy vs. crystal momentum E(k) diagram for a solid (band structure) constitutes the road map for navigating its optical, magnetic, and transport properties. By selecting crystals with specific atom types, composition and symmetries, one could design a target band structure and thus desired properties. A particularly attractive outcome would be to design energy bands that are split into spin components with a momentum-dependent splitting, as envisioned by Pekar and Rashba [Zh. Eksperim. i Teor. Fiz. 47 (1964)], enabling spintronic application. The current paper provides "design principles" for wavevector dependent spin splitting (SS) of energy bands that parallels the traditional Dresselhaus and Rashba spin-orbit coupling (SOC) - induce splitting, but originates from a fundamentally different source -- antiferromagnetism. We identify a few generic AFM prototypes with distinct SS patterns using magnetic symmetry design principles. These tools allow also the identification of specific AFM compounds with SS belonging to different prototypes. A specific compound -- centrosymmetric tetragonal MnF2 -- is used via density functional band structure calculations to quantitatively illustrate one type of AFM SS. Unlike the traditional SOC-induced effects restricted to non-centrosymmetric crystals, we show that antiferromagnetic-induced spin splitting broadens the playing field to include even centrosymmetric compounds, and gives SS comparable in magnitude to the best known ('giant') SOC effects, even without SOC, and consequently does not rely on the often-unstable high atomic number elements required for high SOC. We envision that use of the current design principles to identify an optimal antiferromagnet with spin-split energy bands would be beneficial for efficient spin-charge conversion and spin orbit torque applications without the burden of requiring compounds containing heavy elements. |
| Author | Lin-Ding, Yuan Jun-Wei, Luo Wang, Zhi Zunger, Alex Rashba, Emmanuel I |
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| BackLink | https://doi.org/10.1103/PhysRevB.102.014422$$DView published paper (Access to full text may be restricted) https://doi.org/10.48550/arXiv.1912.12689$$DView paper in arXiv |
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| Snippet | The energy vs. crystal momentum E(k) diagram for a solid (band structure) constitutes the road map for navigating its optical, magnetic, and transport... Phys. Rev. B 102, 014422 (2020) The energy vs. crystal momentum E(k) diagram for a solid (band structure) constitutes the road map for navigating its optical,... |
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| SubjectTerms | Antiferromagnetism Atomic properties Band structure of solids Band theory Bands Crystal structure Energy bands Heavy elements Momentum Optical properties Physics - Materials Science Physics - Mesoscale and Nanoscale Physics Physics - Quantum Physics Spin-orbit interactions Splitting Symmetry Transport properties |
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| Title | Giant momentum-dependent spin splitting in centrosymmetric low Z antiferromagnets |
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