Heisenberg Spin Hamiltonian Derived from a Multiple Grand Canonical Spin Density Functional Theory with a Principal Nonlocal Exchange–Correlation Energy Functional

The Heisenberg spin Hamiltonian, Hex, with spin-exchange coupling constants (Ji,j) between n effective spins (ESs) generated in a polynuclear transition-metal complex was derived from a multiple grand canonical (MGC) spin density functional theory combining a set of 2n−1 mutually independent ES arra...

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Veröffentlicht in:	Journal of the Physical Society of Japan 2022-01, Vol.91 (1), p.1
1. Verfasser:	Kusunoki, Masami
Format:	Artikel
Sprache:	eng
Schlagworte:	Constants Coordination compounds Coupling Density functional theory Electron spin Exchanging Internal energy Operators (mathematics) Permutations Transition metal compounds
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description	The Heisenberg spin Hamiltonian, Hex, with spin-exchange coupling constants (Ji,j) between n effective spins (ESs) generated in a polynuclear transition-metal complex was derived from a multiple grand canonical (MGC) spin density functional theory combining a set of 2n−1 mutually independent ES arrangement (ESA) states defined by the principal GC internal energy functional (UUHFD) by using Dirac's spin-dependent electron-spin permutation operator. The variation principle for minimizing the grand potential in each ESA state yielded independently an orthonormal set of self-consistent natural LCAO-MO's. In all the ESA states, three sets of the expected values of UUHFD, Hex, and Stot2 (Stot is the total spin operator) were combined to formulate n ES densities, and each set of the exchange–correlation density overlap integral ratios {SiES,jES} between iES and jES, and thereby the mean isotropic spin-exchange coupling constants {Ji,j}. The derived formulas were benchmark-tested and demonstrated the best quantitative agreement with 11 experimental results.
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The variation principle for minimizing the grand potential in each ESA state yielded independently an orthonormal set of self-consistent natural LCAO-MO's. In all the ESA states, three sets of the expected values of UUHFD, Hex, and Stot2 (Stot is the total spin operator) were combined to formulate n ES densities, and each set of the exchange–correlation density overlap integral ratios {SiES,jES} between iES and jES, and thereby the mean isotropic spin-exchange coupling constants {Ji,j}. 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The variation principle for minimizing the grand potential in each ESA state yielded independently an orthonormal set of self-consistent natural LCAO-MO's. In all the ESA states, three sets of the expected values of UUHFD, Hex, and Stot2 (Stot is the total spin operator) were combined to formulate n ES densities, and each set of the exchange–correlation density overlap integral ratios {SiES,jES} between iES and jES, and thereby the mean isotropic spin-exchange coupling constants {Ji,j}. 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The variation principle for minimizing the grand potential in each ESA state yielded independently an orthonormal set of self-consistent natural LCAO-MO's. In all the ESA states, three sets of the expected values of UUHFD, Hex, and Stot2 (Stot is the total spin operator) were combined to formulate n ES densities, and each set of the exchange–correlation density overlap integral ratios {SiES,jES} between iES and jES, and thereby the mean isotropic spin-exchange coupling constants {Ji,j}. The derived formulas were benchmark-tested and demonstrated the best quantitative agreement with 11 experimental results.</abstract><cop>Tokyo</cop><pub>The Physical Society of Japan</pub><doi>10.7566/JPSJ.91.014702</doi><orcidid>https://orcid.org/0000-0002-9543-0630</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Constants Coordination compounds Coupling Density functional theory Electron spin Exchanging Internal energy Operators (mathematics) Permutations Transition metal compounds
title	Heisenberg Spin Hamiltonian Derived from a Multiple Grand Canonical Spin Density Functional Theory with a Principal Nonlocal Exchange–Correlation Energy Functional
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