Path Integral Spin Dynamics for Quantum Paramagnets

A path integral method, combined with atomistic spin dynamics simulations, is developed to calculate thermal quantum expectation values using a classical approach. In this study, it is shown how to treat Hamiltonians with non‐linear terms, that are relevant for describing uniaxial anisotropies and m...

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Bibliographic Details
Published inAdvanced Physics Research Vol. 4; no. 8
Main Authors Nussle, Thomas, Thibaudeau, Pascal, Nicolis, Stam
Format Journal Article
LanguageEnglish
Published Wiley 01.08.2025
Wiley-VCH
Subjects
atomistic spin dynamics
Computational Physics
Condensed Matter
Materials Science
paramagnetic hamiltonian
path integrals
Physics
quantum magnetization
Quantum Physics
atomistic spin dynamics
Paramagnetic hamiltonian
spin coherent states
Quantum magnetisation
Path integrals
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Summary:A path integral method, combined with atomistic spin dynamics simulations, is developed to calculate thermal quantum expectation values using a classical approach. In this study, it is shown how to treat Hamiltonians with non‐linear terms, that are relevant for describing uniaxial anisotropies and mechanical constraints. These interactions can be expressed solely through quadratic terms of the spin operator along one axis, that can be identified with the quantization axis. The study has developed a path integral method, which is a classical approach, combined with atomistic spin dynamics simulations to calculate thermal quantum expectation values. This method can handle Hamiltonians with non‐linear terms, which are important for describing uniaxial anisotropies and mechanical constraints. The interactions of these non‐linear terms can be expressed exclusively through quadratic terms of the spin operator along a single axis, which can be identified as the quantization axis.
ISSN:2751-1200
2751-1200
DOI:10.1002/apxr.202400057