Bulk Nanostructured Silicide Thermoelectric Materials by Reversible Hydrogen Absorption–Desorption

The production of bulk nanostructured silicide thermoelectric materials by a reversible hydrogen absorption–desorption process is demonstrated. Here, high‐pressure reactive milling under 100 bar hydrogen is used to decompose the Ca2Si phase into CaH2 and Si. Subsequent vacuum heat treatment results...

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Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2024-05, Vol.20 (21), p.e2208098-n/a
Main Authors: Dirba, Imants, Ablets, Yevhen, Skokov, Konstantin, Adabifiroozjaei, Esmaeil, Molina‐Luna, Leopoldo, Gutfleisch, Oliver
Format: Article
Language:English
Subjects:
Absorption
Decomposition reactions
Desorption
Grain boundaries
Grain size
Heat treating
Heat treatment
Hydrogen
Intermetallic compounds
Nanostructure
nanostructuring
phonon scattering
Precipitates
Silicides
Silicon
Thermal conductivity
Thermoelectric materials
thermoelectrics
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Summary:The production of bulk nanostructured silicide thermoelectric materials by a reversible hydrogen absorption–desorption process is demonstrated. Here, high‐pressure reactive milling under 100 bar hydrogen is used to decompose the Ca2Si phase into CaH2 and Si. Subsequent vacuum heat treatment results in hydrogen desorption and recombination of the constituents into the original phase. By changing the heat treatment temperature, recombination into Ca2Si or Ca5Si3 can be achieved. Most importantly, the advanced synthesis process enables drastic and simple microstructure refinement by more than two orders of magnitude, from a grain size of around 50 µm in the initial ingot to 100–200 nm after the hydrogen absorption–desorption process. Fine precipitates with sizes ranging from 10–50 nm are forming coherently inside the grains. Thus, the route is promising and can be used for reducing thermal conductivity due to phonon scattering from grain boundaries as well as through nanostructuring with second‐phase precipitates. Moreover, the process is environmentally friendly since hydrogen is reversibly absorbed, desorbed, and can be fully recovered. For the first time, the production of bulk nanostructured silicide thermoelectric materials by a reversible hydrogen absorption–desorption process is demonstrated. The advanced synthesis process enables microstructure refinement of more than two orders of magnitude, from around 50 µm in the initial ingot to 100–200 nm. Furthermore, fine 10–50 nm precipitates are formed inside the grains.
ISSN:1613-6810
1613-6829
DOI:10.1002/smll.202208098