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Superexchange

January 01, 1970

Superexchange or Kramers–Anderson superexchange interaction, is a prototypical indirect exchange coupling between neighboring magnetic moments (usually next-nearest neighboring cations, see the schematic illustration of MnO below) by virtue of exchanging electrons through a non-magnetic anion known as the superexchange center. In this way, it differs from direct exchange, in which there is direct overlap of electron wave function from nearest neighboring cations not involving an intermediary anion or exchange center. While direct exchange can be either ferromagnetic or antiferromagnetic, the superexchange interaction is usually antiferromagnetic, preferring opposite alignment of the connected magnetic moments. Similar to the direct exchange, superexchange calls for the combined effect of Pauli exclusion principle and Coulomb's repulsion of the electrons. If the superexchange center and the magnetic moments it connects to are non-collinear, namely the atomic bonds are canted, the superexchange will be accompanied by the antisymmetric exchange known as the Dzyaloshinskii–Moriya interaction, which prefers orthogonal alignment of neighboring magnetic moments. In this situation, the symmetric and antisymmetric contributions compete with each other and can result in versatile magnetic spin textures such as magnetic skyrmions.

Superexchange for MnO

Superexchange was theoretically proposed by Hendrik Kramers in 1934, when he noticed that in crystals like Manganese(II) oxide (MnO), there are manganese atoms that interact with one another despite having nonmagnetic oxygen atoms between them.[1] Phillip Anderson later refined Kramers' model in 1950.[2]

A set of semi-empirical rules were developed by John B. Goodenough and Junjiro Kanamori [ja] in the 1950s.[3][4][5] These rules, now referred to as the Goodenough–Kanamori rules, have proven highly successful in rationalizing the magnetic properties of a wide range of materials on a qualitative level. They are based on the symmetry relations and electron occupancy of the overlapping atomic orbitals (assuming the localized Heitler–London, or valence-bond, model is more representative of the chemical bonding than is the delocalized, or Hund–Mulliken–Bloch, model). Essentially, the Pauli exclusion principle dictates that between two magnetic ions with half-occupied orbitals, which couple through an intermediary non-magnetic ion (e.g. O2−), the superexchange will be strongly anti-ferromagnetic while the coupling between an ion with a filled orbital and one with a half-filled orbital will be ferromagnetic. The coupling between an ion with either a half-filled or filled orbital and one with a vacant orbital can be either antiferromagnetic or ferromagnetic, but generally favors ferromagnetic.[6] When multiple types of interactions are present simultaneously, the antiferromagnetic one is generally dominant, since it is independent of the intra-atomic exchange term.[7] For simple cases, the Goodenough–Kanamori rules readily allow the prediction of the net magnetic exchange expected for the coupling between ions. Complications begin to arise in various situations:

  1. when direct exchange and superexchange mechanisms compete with one another;
  2. when the cation–anion–cation bond angle deviates away from 180°;
  3. when the electron occupancy of the orbitals is non-static, or dynamical;
  4. and when spin–orbit coupling becomes important.

Double exchange is a related magnetic coupling interaction proposed by Clarence Zener to account for electrical transport properties. It differs from superexchange in the following manner: in superexchange, the occupancy of the d-shell of the two metal ions is the same or differs by two, and the electrons are localized. For other occupations (double exchange), the electrons are itinerant (delocalized); this results in the material displaying magnetic exchange coupling, as well as metallic conductivity.

Manganese oxide edit

The p orbitals from oxygen and d orbitals from manganese can form a direct exchange. There is antiferromagnetic order because the singlet state is energetically favoured. This configuration allows a delocalization of the involved electrons due to a lowering of the kinetic energy.[citation needed]

Quantum-mechanical perturbation theory results in an antiferromagnetic interaction of the spins of neighboring Mn atoms with the energy operator (Hamiltonian)

 

where tMn,O is the so-called hopping energy between a Mn 3d and the oxygen p orbitals, while U is a so-called Hubbard energy for Mn. The expression   is the scalar product between the Mn spin-vector operators (Heisenberg model).

References edit

  1. ^ H. A. Kramers (1934). "L'interaction Entre les Atomes Magnétogènes dans un Cristal Paramagnétique". Physica (in French). 1 (1–6): 182. Bibcode:1934Phy.....1..182K. doi:10.1016/S0031-8914(34)90023-9.
  2. ^ P. W. Anderson (1950). "Antiferromagnetism. Theory of Superexchange Interaction". Physical Review. 79 (2): 350. Bibcode:1950PhRv...79..350A. doi:10.1103/PhysRev.79.350.
  3. ^ J. B. Goodenough (1955). "Theory of the Role of Covalence in the Perovskite-Type Manganites [La, M(II)]MnO3". Physical Review. 100 (2): 564. Bibcode:1955PhRv..100..564G. doi:10.1103/PhysRev.100.564.
  4. ^ John B. Goodenough (1958). "An interpretation of the magnetic properties of the perovskite-type mixed crystals La1−xSrxCoO3−λ". Journal of Physics and Chemistry of Solids. 6 (2–3): 287. doi:10.1016/0022-3697(58)90107-0.
  5. ^ J. Kanamori (1959). "Superexchange interaction and symmetry properties of electron orbitals". Journal of Physics and Chemistry of Solids. 10 (2–3): 87. Bibcode:1959JPCS...10...87K. doi:10.1016/0022-3697(59)90061-7.
  6. ^ Lalena, John N.; Cleary, David A.; Hardouin Duparc, Olivier B. M. (2020). Principles of Inorganic Materials Design (3rd ed.). Hoboken: John Wiley & Sons. pp. 382–386. doi:10.1002/9781119486879. ISBN 9781119486831.
  7. ^ H. Weihe; H. U. Güdel (1997). "Quantitative Interpretation of the Goodenough−Kanamori Rules: A Critical Analysis". Inorganic Chemistry. 36 (17): 3632. doi:10.1021/ic961502+. PMID 11670054.

External links edit

  • Erik Koch (2012). "Exchange Mechanisms" (PDF). In E. Pavarini; E. Koch; F. Anders; M. Jarrell (eds.). Correlated Electrons: From Models to Materials. Jülich. ISBN 978-3-89336-796-2.

January 01, 1970
superexchange, this, article, technical, most, readers, understand, please, help, improve, make, understandable, experts, without, removing, technical, details, october, 2022, learn, when, remove, this, message, kramers, anderson, superexchange, interaction, p. This article may be too technical for most readers to understand Please help improve it to make it understandable to non experts without removing the technical details October 2022 Learn how and when to remove this message Superexchange or Kramers Anderson superexchange interaction is a prototypical indirect exchange coupling between neighboring magnetic moments usually next nearest neighboring cations see the schematic illustration of MnO below by virtue of exchanging electrons through a non magnetic anion known as the superexchange center In this way it differs from direct exchange in which there is direct overlap of electron wave function from nearest neighboring cations not involving an intermediary anion or exchange center While direct exchange can be either ferromagnetic or antiferromagnetic the superexchange interaction is usually antiferromagnetic preferring opposite alignment of the connected magnetic moments Similar to the direct exchange superexchange calls for the combined effect of Pauli exclusion principle and Coulomb s repulsion of the electrons If the superexchange center and the magnetic moments it connects to are non collinear namely the atomic bonds are canted the superexchange will be accompanied by the antisymmetric exchange known as the Dzyaloshinskii Moriya interaction which prefers orthogonal alignment of neighboring magnetic moments In this situation the symmetric and antisymmetric contributions compete with each other and can result in versatile magnetic spin textures such as magnetic skyrmions Superexchange for MnO Superexchange was theoretically proposed by Hendrik Kramers in 1934 when he noticed that in crystals like Manganese II oxide MnO there are manganese atoms that interact with one another despite having nonmagnetic oxygen atoms between them 1 Phillip Anderson later refined Kramers model in 1950 2 A set of semi empirical rules were developed by John B Goodenough and Junjiro Kanamori ja in the 1950s 3 4 5 These rules now referred to as the Goodenough Kanamori rules have proven highly successful in rationalizing the magnetic properties of a wide range of materials on a qualitative level They are based on the symmetry relations and electron occupancy of the overlapping atomic orbitals assuming the localized Heitler London or valence bond model is more representative of the chemical bonding than is the delocalized or Hund Mulliken Bloch model Essentially the Pauli exclusion principle dictates that between two magnetic ions with half occupied orbitals which couple through an intermediary non magnetic ion e g O2 the superexchange will be strongly anti ferromagnetic while the coupling between an ion with a filled orbital and one with a half filled orbital will be ferromagnetic The coupling between an ion with either a half filled or filled orbital and one with a vacant orbital can be either antiferromagnetic or ferromagnetic but generally favors ferromagnetic 6 When multiple types of interactions are present simultaneously the antiferromagnetic one is generally dominant since it is independent of the intra atomic exchange term 7 For simple cases the Goodenough Kanamori rules readily allow the prediction of the net magnetic exchange expected for the coupling between ions Complications begin to arise in various situations when direct exchange and superexchange mechanisms compete with one another when the cation anion cation bond angle deviates away from 180 when the electron occupancy of the orbitals is non static or dynamical and when spin orbit coupling becomes important Double exchange is a related magnetic coupling interaction proposed by Clarence Zener to account for electrical transport properties It differs from superexchange in the following manner in superexchange the occupancy of the d shell of the two metal ions is the same or differs by two and the electrons are localized For other occupations double exchange the electrons are itinerant delocalized this results in the material displaying magnetic exchange coupling as well as metallic conductivity Manganese oxide editThe p orbitals from oxygen and d orbitals from manganese can form a direct exchange There is antiferromagnetic order because the singlet state is energetically favoured This configuration allows a delocalization of the involved electrons due to a lowering of the kinetic energy citation needed Quantum mechanical perturbation theory results in an antiferromagnetic interaction of the spins of neighboring Mn atoms with the energy operator Hamiltonian H 1 2 2 t Mn O 2 U S 1 S 2 displaystyle mathcal H 1 2 frac 2t text Mn O 2 U hat S 1 cdot hat S 2 nbsp where tMn O is the so called hopping energy between a Mn 3d and the oxygen p orbitals while U is a so called Hubbard energy for Mn The expression S 1 S 2 displaystyle hat S 1 cdot hat S 2 nbsp is the scalar product between the Mn spin vector operators Heisenberg model References edit H A Kramers 1934 L interaction Entre les Atomes Magnetogenes dans un Cristal Paramagnetique Physica in French 1 1 6 182 Bibcode 1934Phy 1 182K doi 10 1016 S0031 8914 34 90023 9 P W Anderson 1950 Antiferromagnetism Theory of Superexchange Interaction Physical Review 79 2 350 Bibcode 1950PhRv 79 350A doi 10 1103 PhysRev 79 350 J B Goodenough 1955 Theory of the Role of Covalence in the Perovskite Type Manganites La M II MnO3 Physical Review 100 2 564 Bibcode 1955PhRv 100 564G doi 10 1103 PhysRev 100 564 John B Goodenough 1958 An interpretation of the magnetic properties of the perovskite type mixed crystals La1 xSrxCoO3 l Journal of Physics and Chemistry of Solids 6 2 3 287 doi 10 1016 0022 3697 58 90107 0 J Kanamori 1959 Superexchange interaction and symmetry properties of electron orbitals Journal of Physics and Chemistry of Solids 10 2 3 87 Bibcode 1959JPCS 10 87K doi 10 1016 0022 3697 59 90061 7 Lalena John N Cleary David A Hardouin Duparc Olivier B M 2020 Principles of Inorganic Materials Design 3rd ed Hoboken John Wiley amp Sons pp 382 386 doi 10 1002 9781119486879 ISBN 9781119486831 H Weihe H U Gudel 1997 Quantitative Interpretation of the Goodenough Kanamori Rules A Critical Analysis Inorganic Chemistry 36 17 3632 doi 10 1021 ic961502 PMID 11670054 External links editErik Koch 2012 Exchange Mechanisms PDF In E Pavarini E Koch F Anders M Jarrell eds Correlated Electrons From Models to Materials Julich ISBN 978 3 89336 796 2 Retrieved from https en wikipedia org w index php title Superexchange amp oldid 1172173838, wikipedia, wiki, book, books, library,

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