Grain Size-Dependent Thermal Expansion of Nanocrystalline Metals

Pär Olsson; Ibrahim  Awala; Jacob Holmberg-Kasa; Andreas Krause; Mattias  Tidefelt; Oscar  Vigstrand; Denis Music

doi:10.3390/ma16145032

Grain Size-Dependent Thermal Expansion of Nanocrystalline Metals

Pär Olsson, Ibrahim Awala, Jacob Holmberg-Kasa, Andreas Krause, Mattias Tidefelt, Oscar Vigstrand, Denis Music

Malmö universitet

Forskningsoutput: Tidskriftsbidrag › Artikel i vetenskaplig tidskrift › Peer review

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In the present work, we have used classical molecular dynamics and quantum mechanical density functional theory modeling to investigate the grain size-dependent thermal expansion coefficient (CTE) of nanocrystalline Cu. We find that the CTE increases by up to 20% with a gradually decreasing grain size. This behavior emerges as a result of the increased population of occupied anti-bonding states and bond order variation in the grain boundary regions, which contribute to the reduced resistance against thermally-induced bond stretching and dictate the thermal expansion behavior in the small grain size limit. As a part of the present work, we have established a procedure to produce ab initio thermal expansion maps that can be used for the prediction of the grain size-dependent CTE. This can serve as a modeling tool, e.g., to explore the impact of grain boundary impurity segregation on the CTE.

Originalspråk	engelska
Artikelnummer	5032
Antal sidor	13
Tidskrift	Materials
Volym	16
Nummer	14
DOI	https://doi.org/10.3390/ma16145032
Status	Published - 2023 juli 16

Ämnesklassifikation (UKÄ)

Den kondenserade materiens fysik (Här ingår: Materialfysik, nanofysik)
Materialteknik
Teknisk mekanik

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10.3390/ma16145032Licens: CC BY

Olsson_2023cPublicerad version, 1,36 MBLicens: CC BY

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abstract = "In the present work, we have used classical molecular dynamics and quantum mechanical density functional theory modeling to investigate the grain size-dependent thermal expansion coefficient (CTE) of nanocrystalline Cu. We find that the CTE increases by up to 20% with a gradually decreasing grain size. This behavior emerges as a result of the increased population of occupied anti-bonding states and bond order variation in the grain boundary regions, which contribute to the reduced resistance against thermally-induced bond stretching and dictate the thermal expansion behavior in the small grain size limit. As a part of the present work, we have established a procedure to produce ab initio thermal expansion maps that can be used for the prediction of the grain size-dependent CTE. This can serve as a modeling tool, e.g., to explore the impact of grain boundary impurity segregation on the CTE.",

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AU - Holmberg-Kasa, Jacob

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AU - Tidefelt, Mattias

AU - Vigstrand, Oscar

AU - Music, Denis

PY - 2023/7/16

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N2 - In the present work, we have used classical molecular dynamics and quantum mechanical density functional theory modeling to investigate the grain size-dependent thermal expansion coefficient (CTE) of nanocrystalline Cu. We find that the CTE increases by up to 20% with a gradually decreasing grain size. This behavior emerges as a result of the increased population of occupied anti-bonding states and bond order variation in the grain boundary regions, which contribute to the reduced resistance against thermally-induced bond stretching and dictate the thermal expansion behavior in the small grain size limit. As a part of the present work, we have established a procedure to produce ab initio thermal expansion maps that can be used for the prediction of the grain size-dependent CTE. This can serve as a modeling tool, e.g., to explore the impact of grain boundary impurity segregation on the CTE.

AB - In the present work, we have used classical molecular dynamics and quantum mechanical density functional theory modeling to investigate the grain size-dependent thermal expansion coefficient (CTE) of nanocrystalline Cu. We find that the CTE increases by up to 20% with a gradually decreasing grain size. This behavior emerges as a result of the increased population of occupied anti-bonding states and bond order variation in the grain boundary regions, which contribute to the reduced resistance against thermally-induced bond stretching and dictate the thermal expansion behavior in the small grain size limit. As a part of the present work, we have established a procedure to produce ab initio thermal expansion maps that can be used for the prediction of the grain size-dependent CTE. This can serve as a modeling tool, e.g., to explore the impact of grain boundary impurity segregation on the CTE.

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DO - 10.3390/ma16145032

M3 - Article

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Grain Size-Dependent Thermal Expansion of Nanocrystalline Metals

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