Exchange constants for local spin Hamiltonians from tight-binding models
Abstract
We consider the mapping of tight-binding electronic structure theory to a local spin Hamiltonian, based on the adiabatic approximation for spin degrees of freedom in itinerant-electron systems. Local spin Hamiltonians are introduced in order to describe the energy landscape of small magnetic fluctuations, locally around a given spin configuration. They are designed for linear response near a given magnetic state and in general insufficient to capture arbitrarily strong deviations of spin configurations from the equilibrium. In order to achieve this mapping, we include a linear term in the local spin Hamiltonian that, together with the usual bilinear exchange tensor, produces an improved accuracy of effective magnetic Weiss fields for non-collinear states. We also provide examples from tight-binding electronic structure theory, where our implementation of the calculation of exchange constants is based on constraining fields that stabilize an out-of-equilibrium spin configuration. We check our formalism by means of numerical calculations for iron dimers and chains.
Keywords
Cite
@article{arxiv.2103.04726,
title = {Exchange constants for local spin Hamiltonians from tight-binding models},
author = {Simon Streib and Attila Szilva and Vladislav Borisov and Manuel Pereiro and Anders Bergman and Erik Sjöqvist and Anna Delin and Mikhail I. Katsnelson and Olle Eriksson and Danny Thonig},
journal= {arXiv preprint arXiv:2103.04726},
year = {2021}
}
Comments
12 pages, 10 figures