Graphene-carbon nitride interface-geometry effects on thermal rectification: A molecular dynamics simulation

O. Farzadian; C. Spitas; K. V. Kostas

doi:10.1088/1361-6528/abe786

Graphene-carbon nitride interface-geometry effects on thermal rectification: A molecular dynamics simulation

O. Farzadian, C. Spitas, K. V. Kostas

Research output: Journal Publication › Article › peer-review

15 Citations (Scopus)

Abstract

In this paper we expand our previous study on phonon thermal rectification (TR) exhibited in a hybrid graphene-carbon nitride system (G−C₃N) to investigate the system's behavior under a wider range of temperature differences, between the two employed baths, and the effects of media-interface geometry on the rectification factor. Our simulation results reveal a sigmoid relation between TR and temperature difference, with a sample-size depending upper asymptote occurring at generally large temperature differences. The achieved TR values are significant and go up to around 120% for ΔT = 150 K. Furthermore, the consideration of varying media-interface geometries yields a non-negligible effect on TR and highlights areas for further investigation. Finally, calculations of Kapitza resistance at the G-C₃N interface are performed for assisting us in the understanding of interface-geometry effects on TR.

Original language	English
Article number	215403
Journal	Nanotechnology
Volume	32
Issue number	21
DOIs	https://doi.org/10.1088/1361-6528/abe786
Publication status	Published - 21 May 2021
Externally published	Yes

Keywords

Graphene-C3N interface
Molecular dynamics
Thermal rectification

ASJC Scopus subject areas

Bioengineering
General Chemistry
General Materials Science
Mechanics of Materials
Mechanical Engineering
Electrical and Electronic Engineering

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10.1088/1361-6528/abe786

Cite this

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title = "Graphene-carbon nitride interface-geometry effects on thermal rectification: A molecular dynamics simulation",

abstract = "In this paper we expand our previous study on phonon thermal rectification (TR) exhibited in a hybrid graphene-carbon nitride system (G−C3N) to investigate the system's behavior under a wider range of temperature differences, between the two employed baths, and the effects of media-interface geometry on the rectification factor. Our simulation results reveal a sigmoid relation between TR and temperature difference, with a sample-size depending upper asymptote occurring at generally large temperature differences. The achieved TR values are significant and go up to around 120% for ΔT = 150 K. Furthermore, the consideration of varying media-interface geometries yields a non-negligible effect on TR and highlights areas for further investigation. Finally, calculations of Kapitza resistance at the G-C3N interface are performed for assisting us in the understanding of interface-geometry effects on TR.",

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T2 - A molecular dynamics simulation

AU - Farzadian, O.

AU - Spitas, C.

AU - Kostas, K. V.

PY - 2021/5/21

Y1 - 2021/5/21

N2 - In this paper we expand our previous study on phonon thermal rectification (TR) exhibited in a hybrid graphene-carbon nitride system (G−C3N) to investigate the system's behavior under a wider range of temperature differences, between the two employed baths, and the effects of media-interface geometry on the rectification factor. Our simulation results reveal a sigmoid relation between TR and temperature difference, with a sample-size depending upper asymptote occurring at generally large temperature differences. The achieved TR values are significant and go up to around 120% for ΔT = 150 K. Furthermore, the consideration of varying media-interface geometries yields a non-negligible effect on TR and highlights areas for further investigation. Finally, calculations of Kapitza resistance at the G-C3N interface are performed for assisting us in the understanding of interface-geometry effects on TR.

AB - In this paper we expand our previous study on phonon thermal rectification (TR) exhibited in a hybrid graphene-carbon nitride system (G−C3N) to investigate the system's behavior under a wider range of temperature differences, between the two employed baths, and the effects of media-interface geometry on the rectification factor. Our simulation results reveal a sigmoid relation between TR and temperature difference, with a sample-size depending upper asymptote occurring at generally large temperature differences. The achieved TR values are significant and go up to around 120% for ΔT = 150 K. Furthermore, the consideration of varying media-interface geometries yields a non-negligible effect on TR and highlights areas for further investigation. Finally, calculations of Kapitza resistance at the G-C3N interface are performed for assisting us in the understanding of interface-geometry effects on TR.

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Graphene-carbon nitride interface-geometry effects on thermal rectification: A molecular dynamics simulation

Abstract

Keywords

ASJC Scopus subject areas

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