Longitudinal integration measure in classical spin space and its application to first-principle based simulations of ferromagnetic metals

•The form of the integration measure for a classical spin space is derived starting from a very general perspective.•We show that the number of quantum states corresponding to the considered classical spin amplitude is proportional to this amplitude and thus a non-trivial integration measure must be...

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Bibliographic Details
Published in:Journal of magnetism and magnetic materials 2018-09, Vol.461, p.14-18
Main Author: Khmelevskyi, Sergii
Format: Article
Language:English
Subjects:
Approximation
Commutation
Computer simulation
Ferromagnetism
Finite element analysis
First principles
Hamiltonian functions
Magnetic moments
Magnetic properties
Magnetism
Mathematical analysis
Nickel
Parameters
Quantum theory
Simulation
Temperature
Variations
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Summary:•The form of the integration measure for a classical spin space is derived starting from a very general perspective.•We show that the number of quantum states corresponding to the considered classical spin amplitude is proportional to this amplitude and thus a non-trivial integration measure must be used.•Last decades there are enormous effort worldwide to include the fluctuations of magnetic amplitude into the ab initio modeling of the finite temperature properties of itinerant magnetics. It has been motivated by the fact that simple local moment theories fails to provides an adequate description of finite temperature properties in many of important functional magnetic materials.•Moreover, the lack of knowledge of the exact, or at least physically grounded, form of high temperature magnetic entropy plagues the effective use of modern methods of ab initio alloy simulations for Fe-based alloys. Although the derived expressions for the entropy and the measure are very simple, they lead to the very non-trivial consequences as they are different from those have been used to date. The classical Heisenberg type spin Hamiltonian is widely used for simulations of finite temperature properties of magnetic metals often using parameters derived from first principles calculations. In itinerant electron systems, however, the atomic magnetic moments vary their magnitude with temperature and the spin Hamiltonian should thus be extended to incorporate the effects of longitudinal spin fluctuations (LSF). Although the simple phenomenological spin Hamiltonians describing LSF can be efficiently parameterized in the framework of the constrained Local Spin Density Approximation (LSDA) and its extensions, the fundamental problem concerning the integration in classical spin space remains. It is generally unknown how to integrate over the spin magnitude. Two intuitive choices of integration measure have been used up to date – the Murata-Doniach scalar measure and the simple three dimensional vector measure. Here we derive the integration measure by considering a classical limit of the quantum Heisenberg spin Hamiltonian under conditions leading to the proper classical limit of the commutation relations for all values of the classical spin magnitude and calculate the corresponding ratio of the number of quantum states. We show that the number of quantum states corresponding to the considered classical spin magnitude is proportional to this magnitude and thus a non-trivial integrati
ISSN:0304-8853
1873-4766
DOI:10.1016/j.jmmm.2018.04.023