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Autori principali: Simoncelli, Michele, Fournier, Daniele, Marangolo, Massimiliano, Balan, Etienne, Béneut, Keevin, Baptiste, Benoit, Doisneau, Béatrice, Marzari, Nicola, Mauri, Francesco
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2405.13161
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author Simoncelli, Michele
Fournier, Daniele
Marangolo, Massimiliano
Balan, Etienne
Béneut, Keevin
Baptiste, Benoit
Doisneau, Béatrice
Marzari, Nicola
Mauri, Francesco
author_facet Simoncelli, Michele
Fournier, Daniele
Marangolo, Massimiliano
Balan, Etienne
Béneut, Keevin
Baptiste, Benoit
Doisneau, Béatrice
Marzari, Nicola
Mauri, Francesco
contents The thermal conductivities of crystals and glasses vary strongly and with opposite trends upon heating, decreasing in crystals and increasing in glasses. Here, we show--both with first-principles predictions based on the Wigner transport equation and with thermoreflectance experiments--that the dominant transport mechanisms of crystals (particle-like propagation) and glasses (wave-like tunnelling) can coexist and compensate in materials with crystalline bond order and nearly glassy bond geometry. We demonstrate that ideal compensation emerges in a sample of silica in the form of tridymite, carved from a meteorite found in Steinbach (Germany) in 1724, and yields a "propagation-tunneling-invariant" (PTI) conductivity that is independent from temperature and intermediate between the opposite trends of $α$-quartz crystal and silica glass. We show how such PTI conductivity occurs in the quantum regime below the Debye temperature, and can largely persist at high temperatures in a geometrically amorphous tridymite phase found in refractory bricks fired for years in furnaces for steel smelting. Last, we discuss implications to heat transfer in solids exposed to extreme temperature variations, ranging from planetary cooling to heating protocols to reduce the carbon footprint of industrial furnaces.
format Preprint
id arxiv_https___arxiv_org_abs_2405_13161
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Temperature-invariant heat conductivity from compensating crystalline and glassy transport: from the Steinbach meteorite to furnace bricks
Simoncelli, Michele
Fournier, Daniele
Marangolo, Massimiliano
Balan, Etienne
Béneut, Keevin
Baptiste, Benoit
Doisneau, Béatrice
Marzari, Nicola
Mauri, Francesco
Materials Science
The thermal conductivities of crystals and glasses vary strongly and with opposite trends upon heating, decreasing in crystals and increasing in glasses. Here, we show--both with first-principles predictions based on the Wigner transport equation and with thermoreflectance experiments--that the dominant transport mechanisms of crystals (particle-like propagation) and glasses (wave-like tunnelling) can coexist and compensate in materials with crystalline bond order and nearly glassy bond geometry. We demonstrate that ideal compensation emerges in a sample of silica in the form of tridymite, carved from a meteorite found in Steinbach (Germany) in 1724, and yields a "propagation-tunneling-invariant" (PTI) conductivity that is independent from temperature and intermediate between the opposite trends of $α$-quartz crystal and silica glass. We show how such PTI conductivity occurs in the quantum regime below the Debye temperature, and can largely persist at high temperatures in a geometrically amorphous tridymite phase found in refractory bricks fired for years in furnaces for steel smelting. Last, we discuss implications to heat transfer in solids exposed to extreme temperature variations, ranging from planetary cooling to heating protocols to reduce the carbon footprint of industrial furnaces.
title Temperature-invariant heat conductivity from compensating crystalline and glassy transport: from the Steinbach meteorite to furnace bricks
topic Materials Science
url https://arxiv.org/abs/2405.13161