Thermostructural Characterization of Silicon Carbide Nanocomposite Materials via Molecular Dynamics Simulations

Jose M. Ortiz-Roldan; Francisco Montero-Chacón; Elena Garcia-Perez; Sofía Calero; A. Rabdel Ruiz-Salvador; Said Hamad

doi:10.1080/09243046.2021.2001988

Thermostructural Characterization of Silicon Carbide Nanocomposite Materials via Molecular Dynamics Simulations

Jose M. Ortiz-Roldan, Francisco Montero-Chacón, Elena Garcia-Perez, Sofía Calero, A. Rabdel Ruiz-Salvador, Said Hamad (Corresponding author)

Materials Simulation & Modelling

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

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In this paper, we investigate the thermostructural properties of a type of silicon-based nanomaterials, which we refer to as SiC@Si nanocomposites, formed by SiC crystalline nanoparticles (with the cubic phase), embedded within an amorphous Si matrix. We have followed an in silico approach to characterize the mechanical and thermal behaviour of these materials, by calculating the elastic constants, uniaxial stress-strain curves, coefficients of thermal expansion, and specific heats, at different temperatures, using interatomic potential calculations. The results obtained from our simulations suggest that this type of material presents enhanced thermal resistance features, making it suitable to be used in devices subjected to big temperature changes, such as heat sinks in micro and nanoelectronics, solar energy harvesters at high temperatures, power electronics, or in other applications in which good thermomechanical properties are required.

Originele taal-2	Engels
Pagina's (van-tot)	485-504
Aantal pagina's	20
Tijdschrift	Advanced Composite Materials
Volume	31
Nummer van het tijdschrift	5
Vroegere onlinedatum	21 dec. 2021
DOI's	https://doi.org/10.1080/09243046.2021.2001988
Status	Gepubliceerd - 2022

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Publisher Copyright:
© 2021 Japan Society for Composite Materials, Korean Society for Composite Materials and Informa UK Limited, trading as Taylor & Francis Group.

Financiering

The authors acknowledge the partial funding provided by the Spanish Ministry of Education, Culture and Sport (FPU14/01094), European Research Council through the ERC Starting Grant (ERC2011-StG-279520-RASPA), and Abengoa S.A. (VMD Platform project). S. H. acknowledges funding from the Agencia Estatal de Investigación and the Ministerio de Ciencia, Innovación y Universidades, of Spain (PID2019-110430G B-C22), and from the EU FEDER Framework 2014-2020 and Consejería de Economía, Conocimiento, Empresas y Universidad (FEDER-UPO-1265695). We would also like to thank the high-performance computer centres Alhambra and C3UPO (at the Universities of Granada and Pablo de Olavide, respectively), for providing us computer resources to carry out the work.

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10.1080/09243046.2021.2001988

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title = "Thermostructural Characterization of Silicon Carbide Nanocomposite Materials via Molecular Dynamics Simulations",

abstract = "In this paper, we investigate the thermostructural properties of a type of silicon-based nanomaterials, which we refer to as SiC@Si nanocomposites, formed by SiC crystalline nanoparticles (with the cubic phase), embedded within an amorphous Si matrix. We have followed an in silico approach to characterize the mechanical and thermal behaviour of these materials, by calculating the elastic constants, uniaxial stress-strain curves, coefficients of thermal expansion, and specific heats, at different temperatures, using interatomic potential calculations. The results obtained from our simulations suggest that this type of material presents enhanced thermal resistance features, making it suitable to be used in devices subjected to big temperature changes, such as heat sinks in micro and nanoelectronics, solar energy harvesters at high temperatures, power electronics, or in other applications in which good thermomechanical properties are required.",

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author = "Ortiz-Roldan, {Jose M.} and Francisco Montero-Chac{\'o}n and Elena Garcia-Perez and Sof{\'i}a Calero and Ruiz-Salvador, {A. Rabdel} and Said Hamad",

note = "Funding Information: The authors acknowledge the partial funding provided by the Spanish Ministry of Education, Culture and Sport (FPU14/01094), European Research Council through the ERC Starting Grant (ERC2011-StG-279520-RASPA), and Abengoa S.A. (VMD Platform project). S. H. acknowledges funding from the Agencia Estatal de Investigaci{\'o}n and the Ministerio de Ciencia, Innovaci{\'o}n y Universidades, of Spain (PID2019-110430G B-C22), and from the EU FEDER Framework 2014-2020 and Consejer{\'i}a de Econom{\'i}a, Conocimiento, Empresas y Universidad (FEDER-UPO-1265695). We would also like to thank the high-performance computer centres Alhambra and C3UPO (at the Universities of Granada and Pablo de Olavide, respectively), for providing us computer resources to carry out the work. ",

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AU - Ortiz-Roldan, Jose M.

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AU - Calero, Sofía

AU - Ruiz-Salvador, A. Rabdel

AU - Hamad, Said

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PY - 2022

Y1 - 2022

N2 - In this paper, we investigate the thermostructural properties of a type of silicon-based nanomaterials, which we refer to as SiC@Si nanocomposites, formed by SiC crystalline nanoparticles (with the cubic phase), embedded within an amorphous Si matrix. We have followed an in silico approach to characterize the mechanical and thermal behaviour of these materials, by calculating the elastic constants, uniaxial stress-strain curves, coefficients of thermal expansion, and specific heats, at different temperatures, using interatomic potential calculations. The results obtained from our simulations suggest that this type of material presents enhanced thermal resistance features, making it suitable to be used in devices subjected to big temperature changes, such as heat sinks in micro and nanoelectronics, solar energy harvesters at high temperatures, power electronics, or in other applications in which good thermomechanical properties are required.

AB - In this paper, we investigate the thermostructural properties of a type of silicon-based nanomaterials, which we refer to as SiC@Si nanocomposites, formed by SiC crystalline nanoparticles (with the cubic phase), embedded within an amorphous Si matrix. We have followed an in silico approach to characterize the mechanical and thermal behaviour of these materials, by calculating the elastic constants, uniaxial stress-strain curves, coefficients of thermal expansion, and specific heats, at different temperatures, using interatomic potential calculations. The results obtained from our simulations suggest that this type of material presents enhanced thermal resistance features, making it suitable to be used in devices subjected to big temperature changes, such as heat sinks in micro and nanoelectronics, solar energy harvesters at high temperatures, power electronics, or in other applications in which good thermomechanical properties are required.

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Thermostructural Characterization of Silicon Carbide Nanocomposite Materials via Molecular Dynamics Simulations

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