Eigenfield expansion technique for efficient computation of field-swept fixed-frequency spectra from relaxation master equations

Artigo Acesso aberto Revisado por pares

Eigenfield expansion technique for efficient computation of field-swept fixed-frequency spectra from relaxation master equations

1973; American Institute of Physics; Volume: 59; Issue: 2 Linguagem: Inglês

10.1063/1.1680104

ISSN

1520-9032

Autores

R. Linn Belford, Geneva G. Belford,

Tópico(s)

Magneto-Optical Properties and Applications

Resumo

If the Hamiltonian and Liouville operators of a spectral intensity problem are functions of a field parameter x computation of the intensity as a function of x requires, in effect, inversion of a different large matrix for each value of x. Here we show that when the Liouville operator is a polynomial in x, with operator coefficients, solution of one generalized eigenvalue problem followed by a single solution of a system of linear equations yields the intensity for all x. This formulation promises to save large amounts of computational time, particularly for electron paramagnetic resonance problems involving large zero-field splittings.

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Eigenfield expansion technique for efficient computation of field-swept fixed-frequency spectra from relaxation master equations