Phonons, magnons, and lattice thermal transport in antiferromagnetic semiconductor MnTe

Sai Mu; Raphaël P. Hermann; Stéphane Gorsse; Huaizhou Zhao; Michael E. Manley; Randy S. Fishman; L. Lindsay

doi:10.1103/PhysRevMaterials.3.025403

Phonons, magnons, and lattice thermal transport in antiferromagnetic semiconductor MnTe

Sai Mu, Raphaël P. Hermann, Stéphane Gorsse, Huaizhou Zhao, Michael E. Manley, Randy S. Fishman, L. Lindsay

Research output: Contribution to journal › Article › peer-review

38 Scopus citations

Abstract

The antiferromagnetic semiconductor MnTe has recently attracted attention for spintronics and high-performance thermoelectric applications. However, little is known about its vibrational and thermal transport properties and how these might relate to the electronic and magnetic structure, particularly as related to 3d Mn orbital correlations. Here, we calculate a physically justified Coulomb correlation parameter within the DFT+U framework. We couple this framework with the Heisenberg Hamiltonian and first-principles Boltzmann transport to understand the magnetic, vibrational, and phonon thermal transport properties of MnTe. We also perform inelastic neutron and nuclear inelastic x-ray scattering measurements of the total and partial phonon density of states, respectively. Very good agreement is obtained with the measured and calculated phonon density of states, and with available measurements for the band gap, local magnetic moments, Néel temperature, magnon dispersion, thermal conductivity, and phonon dispersion. This study demonstrates that the vibrational and magnetic degrees of freedom are not strongly coupled in MnTe, and provides a more comprehensive picture of this technologically promising material.

Original language	English
Article number	025403
Journal	Physical Review Materials
Volume	3
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevMaterials.3.025403
State	Published - Feb 11 2019

Funding

This work was supported by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences, Materials Sciences and Engineering Division. Portions of this research used resources at the Spallation Neutron Source, a U.S. DOE Office of Science User Facility operated by the Oak Ridge National Laboratory and beam line ID22N at the European Synchrotron Radiation Facility (ESRF), Grenoble, France. Dr. Ilya Sergueev and Dr. Paula Fichtl are acknowledged for support during data acquisition at ID22N, SNS. Dr. Douglas Abernathy is acknowledged for support during data acquisition at ARCS, SNS. H.Z. acknowledges the funding support from the National Natural Science Foundation of China (NSFC) under Grants No. 51572287 and No. U1601213.

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title = "Phonons, magnons, and lattice thermal transport in antiferromagnetic semiconductor MnTe",

abstract = "The antiferromagnetic semiconductor MnTe has recently attracted attention for spintronics and high-performance thermoelectric applications. However, little is known about its vibrational and thermal transport properties and how these might relate to the electronic and magnetic structure, particularly as related to 3d Mn orbital correlations. Here, we calculate a physically justified Coulomb correlation parameter within the DFT+U framework. We couple this framework with the Heisenberg Hamiltonian and first-principles Boltzmann transport to understand the magnetic, vibrational, and phonon thermal transport properties of MnTe. We also perform inelastic neutron and nuclear inelastic x-ray scattering measurements of the total and partial phonon density of states, respectively. Very good agreement is obtained with the measured and calculated phonon density of states, and with available measurements for the band gap, local magnetic moments, N{\'e}el temperature, magnon dispersion, thermal conductivity, and phonon dispersion. This study demonstrates that the vibrational and magnetic degrees of freedom are not strongly coupled in MnTe, and provides a more comprehensive picture of this technologically promising material.",

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AU - Mu, Sai

AU - Hermann, Raphaël P.

AU - Gorsse, Stéphane

AU - Zhao, Huaizhou

AU - Manley, Michael E.

AU - Fishman, Randy S.

AU - Lindsay, L.

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N2 - The antiferromagnetic semiconductor MnTe has recently attracted attention for spintronics and high-performance thermoelectric applications. However, little is known about its vibrational and thermal transport properties and how these might relate to the electronic and magnetic structure, particularly as related to 3d Mn orbital correlations. Here, we calculate a physically justified Coulomb correlation parameter within the DFT+U framework. We couple this framework with the Heisenberg Hamiltonian and first-principles Boltzmann transport to understand the magnetic, vibrational, and phonon thermal transport properties of MnTe. We also perform inelastic neutron and nuclear inelastic x-ray scattering measurements of the total and partial phonon density of states, respectively. Very good agreement is obtained with the measured and calculated phonon density of states, and with available measurements for the band gap, local magnetic moments, Néel temperature, magnon dispersion, thermal conductivity, and phonon dispersion. This study demonstrates that the vibrational and magnetic degrees of freedom are not strongly coupled in MnTe, and provides a more comprehensive picture of this technologically promising material.

AB - The antiferromagnetic semiconductor MnTe has recently attracted attention for spintronics and high-performance thermoelectric applications. However, little is known about its vibrational and thermal transport properties and how these might relate to the electronic and magnetic structure, particularly as related to 3d Mn orbital correlations. Here, we calculate a physically justified Coulomb correlation parameter within the DFT+U framework. We couple this framework with the Heisenberg Hamiltonian and first-principles Boltzmann transport to understand the magnetic, vibrational, and phonon thermal transport properties of MnTe. We also perform inelastic neutron and nuclear inelastic x-ray scattering measurements of the total and partial phonon density of states, respectively. Very good agreement is obtained with the measured and calculated phonon density of states, and with available measurements for the band gap, local magnetic moments, Néel temperature, magnon dispersion, thermal conductivity, and phonon dispersion. This study demonstrates that the vibrational and magnetic degrees of freedom are not strongly coupled in MnTe, and provides a more comprehensive picture of this technologically promising material.

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Phonons, magnons, and lattice thermal transport in antiferromagnetic semiconductor MnTe

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