Electron-Transparent Thermoelectric Coolers Demonstrated with Nanoparticle and Condensation Thermometry

Electron-Transparent Thermoelectric Coolers Demonstrated with Nanoparticle and Condensation Thermometry

More efficient thermoelectric devices would revolutionize refrigeration and energy production, and low-dimensional thermoelectric materials are predicted to be more efficient than their bulk counterparts. But nanoscale thermoelectric devices generate thermal gradients on length scales that are too s...

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Bibliographic Details
Published in:ACS nano Vol. 14; no. 9; pp. 11510 - 11517
Main Authors: Hubbard, William A, Mecklenburg, Matthew, Lodico, Jared J, Chen, Yueyun, Ling, Xin Yi, Patil, Roshni, Kessel, W. Andrew, Flatt, Graydon J. K, Chan, Ho Leung, Vareskic, Bozo, Bal, Gurleen, Zutter, Brian, Regan, B. C
Format: Journal Article
Language:English
Published: American Chemical Society 22-09-2020
Subjects:
exfoliated
thermoelectric
EELS
EBIC
condensation
bismuth telluride
STEM
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Summary:More efficient thermoelectric devices would revolutionize refrigeration and energy production, and low-dimensional thermoelectric materials are predicted to be more efficient than their bulk counterparts. But nanoscale thermoelectric devices generate thermal gradients on length scales that are too small to resolve with traditional thermometry methods. Here we fabricate, using single-crystal bismuth telluride (Bi2Te3) and antimony/bismuth telluride (Sb2–x Bi x Te3) flakes exfoliated from commercially available bulk materials, functional thermoelectric coolers (TECs) that are only 100 nm thick. These devices are the smallest TECs ever demonstrated by a factor of 104. After depositing indium nanoparticles to serve as nanothermometers, we measure the heating and cooling produced by the devices with plasmon energy expansion thermometry (PEET), a high-spatial-resolution, transmission electron microscopy (TEM)-based thermometry technique, demonstrating a ΔT = −21 ± 4 K from room temperature. We also establish proof-of-concept for condensation thermometry, a quantitative temperature-change mapping technique with a spatial precision of ≲300 nm.
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ISSN:1936-0851
1936-086X
DOI:10.1021/acsnano.0c03958