Energy Flux Effect in the One-Dimensional Spin-1/2 XX Model of Magnetoelectric. Lagrange Multiplier Method

Authors

  • O.R. Baran Institute for Condensed Matter Physics, Nat. Acad. of Sci. of Ukraine

DOI:

https://doi.org/10.15407/ujpe66.10.890

Keywords:

one-dimensional XX model, magnetoelectric, nonequilibrium steady states, energy flux, Lagrange multiplier method

Abstract

The Lagrange multiplier method is applied to study a nonequilibrium steady state with energy flux in the one-dimensional spin-1/2 XX model of a magnetoelectric with the Katsura–Nagaosa–Balatsky mechanism at sufficiently low temperatures. With the help of the Jordan–Wigner transformation, the problem is reduced to that with the Hamiltonian for spinless noninteracting fermions and can be solved exactly. A number of phase diagrams are plotted, and the dependences of the magnetization, electric polarization, and various susceptibilities on the magnetic and electric fields, as well as on the energy flux, are calculated.

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Published

2021-11-01

How to Cite

Baran, O. (2021). Energy Flux Effect in the One-Dimensional Spin-1/2 XX Model of Magnetoelectric. Lagrange Multiplier Method. Ukrainian Journal of Physics, 66(10), 890. https://doi.org/10.15407/ujpe66.10.890

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Section

Physics of magnetic phenomena and physics of ferroics