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Hauptverfasser: Razeghi, Mohammadali, Spiece, Jean, Fonck, Valentin, Zhang, Yao, Rohde, Michael, Joris, Rikkie, Dobson, Philip S., Weaver, Jonathan M. R., Pereira, Lino da Costa, Granville, Simon, Gehring, Pascal
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2403.13598
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author Razeghi, Mohammadali
Spiece, Jean
Fonck, Valentin
Zhang, Yao
Rohde, Michael
Joris, Rikkie
Dobson, Philip S.
Weaver, Jonathan M. R.
Pereira, Lino da Costa
Granville, Simon
Gehring, Pascal
author_facet Razeghi, Mohammadali
Spiece, Jean
Fonck, Valentin
Zhang, Yao
Rohde, Michael
Joris, Rikkie
Dobson, Philip S.
Weaver, Jonathan M. R.
Pereira, Lino da Costa
Granville, Simon
Gehring, Pascal
contents Solid-state cooling devices offer compact, quiet, reliable and environmentally friendly solutions that currently rely primarily on the thermoelectric (TE) effect. Despite more than two centuries of research, classical thermoelectric coolers suffer from low efficiency which hampers wider application. In this study, the less researched Anomalous Ettingshausen effect (AEE), a transverse thermoelectric phenomenon, is presented as a new approach for on-chip cooling. This effect can be boosted in materials with non-trivial band topologies as demonstrated in the Heusler alloy $\text{Co}_2\text{MnGa}$. Enabled by the high quality of our material, in situ scanning thermal microscopy experiments reveal a record-breaking anomalous Ettingshausen coefficient of $-2.1$~mV in $μ$m-sized on-chip cooling devices at room temperature. A significant 44\% of the effect is contributed by the intrinsic topological properties, in particular the Berry curvature of $\text{Co}_2\text{MnGa}$, emphasising the unique potential of magnetic Weyl semimetals for high-performance spot cooling in nanostructures.
format Preprint
id arxiv_https___arxiv_org_abs_2403_13598
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Record-high Anomalous Ettingshausen effect in a micron-sized magnetic Weyl semimetal on-chip cooler
Razeghi, Mohammadali
Spiece, Jean
Fonck, Valentin
Zhang, Yao
Rohde, Michael
Joris, Rikkie
Dobson, Philip S.
Weaver, Jonathan M. R.
Pereira, Lino da Costa
Granville, Simon
Gehring, Pascal
Mesoscale and Nanoscale Physics
Solid-state cooling devices offer compact, quiet, reliable and environmentally friendly solutions that currently rely primarily on the thermoelectric (TE) effect. Despite more than two centuries of research, classical thermoelectric coolers suffer from low efficiency which hampers wider application. In this study, the less researched Anomalous Ettingshausen effect (AEE), a transverse thermoelectric phenomenon, is presented as a new approach for on-chip cooling. This effect can be boosted in materials with non-trivial band topologies as demonstrated in the Heusler alloy $\text{Co}_2\text{MnGa}$. Enabled by the high quality of our material, in situ scanning thermal microscopy experiments reveal a record-breaking anomalous Ettingshausen coefficient of $-2.1$~mV in $μ$m-sized on-chip cooling devices at room temperature. A significant 44\% of the effect is contributed by the intrinsic topological properties, in particular the Berry curvature of $\text{Co}_2\text{MnGa}$, emphasising the unique potential of magnetic Weyl semimetals for high-performance spot cooling in nanostructures.
title Record-high Anomalous Ettingshausen effect in a micron-sized magnetic Weyl semimetal on-chip cooler
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2403.13598