Abstract
The interplay of magnons and phonons can induce strong temperature variations in the magnetic exchange interactions, leading to changes in the magnetothermal response. This is a central mechanism in many magnetic phenomena, and in the new field of Spin Caloritronics, which focuses on the combination of heat and spin currents. Boson model systems have previously been developed to describe the magnon-phonon coupling but, until recently, studies rely on empirical parameters. In this paper, we propose a first-principles approach to describe the dependence of the magnetic exchange integrals on phonon renormalization, leading to changes in the magnon dispersion as a function of temperature. The temperature enters into the spin dynamics (by introducing fluctuations) as well as in the magnetic exchange itself. Depending on the strength of the coupling, these two temperatures may or may not be equilibrated, yielding different regimes. We test our approach in typical and well-known ferromagnetic materials: Ni, Fe, and Permalloy. We compare our results to recent experiments on the spin-wave stiffness, and discuss departures from Bloch's law and parabolic dispersion.
| Original language | English |
|---|---|
| Article number | 214417 |
| Journal | Physical Review B |
| Volume | 97 |
| Issue number | 21 |
| DOIs | |
| Publication status | Published - 14 Jun 2018 |
| Externally published | Yes |
Bibliographical note
Publisher Copyright:© 2018 American Physical Society.
Funding
The authors acknowledge two A.R.C. grants (TheMoTherm 10/15-03 and AIMED 15/19-09) from the Communauté Française de Belgique; M.D.G. acknowledges an F.R.I.A. grant (No. 1.E051.12), also from the Communauté Française de Belgique. Part of this research was performed while M.D.G. was research assistant at the Institute of Physical Chemistry and National Center for Computational Design and Discovery of Novel Materials, Department of Chemistry, University of Basel (Switzerland) as well as visiting the Institute for Pure and Applied Mathematics (IPAM), which is supported by the National Science Foundation. T.A.O. acknowledges the Marie Curie incoming BeIPD-COFUND fellowship program at the University of Liège. A.H.R. acknowledges the support from the DMREF-NSF Projects No. 1434897, No. SI2-SSE 1740111, and No. DOE DE-SC0016176. Computer time was made available by PRACE-2IP, 3IP, and 4IP, and on Archer and Salomon (EU Grants No. RI-283493, No. RI-312763, and No. 653838), CECI, SEGI-ULg, and Zenobe hosted by CENAERO (GA 1117545) and Extreme Science and Engineering Discovery Environment (XSEDE), which is supported by National Science Foundation (US) Grant No. OCI-1053575 with the Stampede 2 and Bridges supercomputers.
| Funders | Funder number |
|---|---|
| A.R.C. | AIMED 15/19-09, 10/15-03 |
| CECI | |
| Communauté Française de Belgique | |
| DMREF-NSF | 653838, PRACE-2IP, 4IP, RI-312763, SI2-SSE 1740111, DOE DE-SC0016176, RI-283493 |
| Extreme Science and Engineering Discovery Environment | |
| F.R.I.A. | |
| SEGI-ULg | GA 1117545 |
| XSEDE | OCI-1053575 |
| National Science Foundation | 1740111 |
| Directorate for Mathematical and Physical Sciences | 1434897 |
| University of Bern | |
| European Union (Marie Curie Programme) | |
| University of Liege |