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Autori principali: Athar, Shoeb, Guazzagaloppa, Jeremy, Boyrie, Fabrice, Huillet, Cedric, Jund, Philippe
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2601.00016
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author Athar, Shoeb
Guazzagaloppa, Jeremy
Boyrie, Fabrice
Huillet, Cedric
Jund, Philippe
author_facet Athar, Shoeb
Guazzagaloppa, Jeremy
Boyrie, Fabrice
Huillet, Cedric
Jund, Philippe
contents Thermoelectric generators (TEGs) based on commercially used thermal super-insulating materials can facilitate sustainable and large-scale ambient waste heat recovery while bequeathing an added economic and environmental value to thermal insulations in industry. This requires the optimization of the thermoelectric (TE) properties through electrical functionalization of such materials. Moreover, the associated engineering challenges of assembling TEG modules must be overcome. Herein, we propose using super-insulating Resorcinol-formaldehyde (RF) carbogels for scalable and sustainable TE applications through their electrical functionalization. Using a combination of a pyrolysis process and carbon fibers insertion, we achieved an increment by 12 orders of magnitude in electrical conductivity as well as ZT whilst retaining their intrinsic ultralow thermal conductivity (<50 mW/mK). A TE module in the form of a thermoelectric vacuum insulation panel (TVIP), was then fabricated using only a p-type material, to demonstrate a proof-of-concept self-powered WiFi-based vacuum-failure detection application in confined spaces in automobiles or aeronautics. Finally, by extrapolating the optimized output power and with a CAD-assisted assembly of a large TEG module (1000 cm2), the potential of scalable low-grade waste heat recovery is discussed.
format Preprint
id arxiv_https___arxiv_org_abs_2601_00016
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Carbogels for sustainable and scalable thermoelectric applications
Athar, Shoeb
Guazzagaloppa, Jeremy
Boyrie, Fabrice
Huillet, Cedric
Jund, Philippe
Applied Physics
Materials Science
Thermoelectric generators (TEGs) based on commercially used thermal super-insulating materials can facilitate sustainable and large-scale ambient waste heat recovery while bequeathing an added economic and environmental value to thermal insulations in industry. This requires the optimization of the thermoelectric (TE) properties through electrical functionalization of such materials. Moreover, the associated engineering challenges of assembling TEG modules must be overcome. Herein, we propose using super-insulating Resorcinol-formaldehyde (RF) carbogels for scalable and sustainable TE applications through their electrical functionalization. Using a combination of a pyrolysis process and carbon fibers insertion, we achieved an increment by 12 orders of magnitude in electrical conductivity as well as ZT whilst retaining their intrinsic ultralow thermal conductivity (<50 mW/mK). A TE module in the form of a thermoelectric vacuum insulation panel (TVIP), was then fabricated using only a p-type material, to demonstrate a proof-of-concept self-powered WiFi-based vacuum-failure detection application in confined spaces in automobiles or aeronautics. Finally, by extrapolating the optimized output power and with a CAD-assisted assembly of a large TEG module (1000 cm2), the potential of scalable low-grade waste heat recovery is discussed.
title Carbogels for sustainable and scalable thermoelectric applications
topic Applied Physics
Materials Science
url https://arxiv.org/abs/2601.00016