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Hauptverfasser: Koster, Karl G., Hise, Jackson, Heremans, Joseph P., Goldberger, Joshua E.
Format: Preprint
Veröffentlicht: 2023
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Online-Zugang:https://arxiv.org/abs/2310.14467
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author Koster, Karl G.
Hise, Jackson
Heremans, Joseph P.
Goldberger, Joshua E.
author_facet Koster, Karl G.
Hise, Jackson
Heremans, Joseph P.
Goldberger, Joshua E.
contents Materials able to rapidly switch between thermally conductive states by external stimuli such as electric or magnetic fields can be used as all-solid-state thermal switches and open a myriad of applications in heat management, power generation and cooling. Here, we show that the large magnetoresistance that occurs in the highly conducting semimetal $α$-WSi$_{2}$ single crystals leads to dramatically large changes in thermal conductivity at temperatures <100 K. At temperatures <20 K, where electron-phonon scattering is minimized, the thermal conductivity switching ratio between zero field and a 9T applied field can be >7. We extract the electronic and lattice components of the from the thermal conductivity measurements and show that the Lorenz number for this material approximates the theoretical value of L$_{0}$. From the heat capacity and thermal diffusivity, the speed of thermal conductivity switching is estimated to range from 1 x 10$^{-4}$ seconds at 5 K to 0.2 seconds at 100 K for a 5-mm long sample. This work shows that WSi$_{2}$, a highly conducting multi-carrier semimetal, is a promising thermal switch component for low-temperature applications such cyclical adiabatic demagnetization cooling, a technique that would enable replacing $^{3}$He-based refrigerators.
format Preprint
id arxiv_https___arxiv_org_abs_2310_14467
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Giant Magnetothermal Conductivity Switching in Semimetallic WSi$_{2}$ Single Crystals
Koster, Karl G.
Hise, Jackson
Heremans, Joseph P.
Goldberger, Joshua E.
Materials Science
Materials able to rapidly switch between thermally conductive states by external stimuli such as electric or magnetic fields can be used as all-solid-state thermal switches and open a myriad of applications in heat management, power generation and cooling. Here, we show that the large magnetoresistance that occurs in the highly conducting semimetal $α$-WSi$_{2}$ single crystals leads to dramatically large changes in thermal conductivity at temperatures <100 K. At temperatures <20 K, where electron-phonon scattering is minimized, the thermal conductivity switching ratio between zero field and a 9T applied field can be >7. We extract the electronic and lattice components of the from the thermal conductivity measurements and show that the Lorenz number for this material approximates the theoretical value of L$_{0}$. From the heat capacity and thermal diffusivity, the speed of thermal conductivity switching is estimated to range from 1 x 10$^{-4}$ seconds at 5 K to 0.2 seconds at 100 K for a 5-mm long sample. This work shows that WSi$_{2}$, a highly conducting multi-carrier semimetal, is a promising thermal switch component for low-temperature applications such cyclical adiabatic demagnetization cooling, a technique that would enable replacing $^{3}$He-based refrigerators.
title Giant Magnetothermal Conductivity Switching in Semimetallic WSi$_{2}$ Single Crystals
topic Materials Science
url https://arxiv.org/abs/2310.14467