An insight into thermal properties of BC3-graphene hetero-nanosheets: a molecular dynamics study

Dehaghani, Maryam Zarghami; Molaei, Fatemeh; Yousefi, Farrokh; Sajadi, S. Mohammad; Esmaeili, Amin; Mohaddespour, Ahmad; Farzadian, Omid; Habibzadeh, Sajjad; Mashhadzadeh, Amin Hamed; Spitas, Christos; Saeb, Mohammad Reza

doi:10.1038/s41598-021-02576-6

Cited by 17 publications

(3 citation statements)

References 46 publications

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“…Figure 5 depicts the temperature profile of a graphene/biphenylene hybrid nanoribbon with a length of 24 nm at room temperature and a temperature gradient of 40 K. The temperature profile of this hybrid nanoribbon exhibits a discontinuity at the interface position (placed in the middle) at which a significant temperature drop is recorded. This effect is attributed to the variation of atomic structure at the two sides of the interface which causes phonon scattering and consequently a temperature drop (T g ), which for our case equals to 18.4 K [30]. A similar behavior in the steady-state temperature profile for graphene-boron nitride heterostructure across its interface was reported by Li et al [31].…”

Section: Heat Transport In Graphene/biphenylene Hybrid Nanoribbonsupporting

confidence: 85%

A theoretical insight into phonon heat transport in graphene/biphenylene superlattice nanoribbons: a molecular dynamic study

et al. 2022

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Manipulating the thermal conductivity of nanomaterials is an efficacious approach to fabricate tailor-made nanodevices for thermoelectric applications. To this end, superlattice nanostructures can be used to achieve minimal thermal conductivity for the employed nanomaterials. Two-dimensional biphenylene is a recently-synthesized sp2-hybridized allotrope of carbon atoms that can be employed in superlattice nanonstructures and therefore further investigation in this context is due. In this study, we first determined the thermal conductivity of biphenylene at 142.8 W.m-1.K-1 which is significantly lower than that of graphene. As a second step, we studied the effect of the superlattice period ( ) on thermal conductivities of the employed graphene/biphenylene superlattice nanoribbons, using the molecular dynamics simulation. We calculated a minimum thermal conductivity of 105.5 W.m-1k-1 at = 5 nm which indicates an achieved thermal conductivity reduction of approximately 97% and 26% when compared to pristine graphene and biphenylene, respectively. This superlattice period denotes the phonon coherent length at which the wave-like behavior of phonons starts prevailing over the particlelike behavior. Finally, the effects of temperature and temperature gradient on the thermal conductivity of superlattice were also investigated.

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Section: Heat Transport In Graphene/biphenylene Hybrid Nanoribbonsupporting

confidence: 85%

A theoretical insight into phonon heat transport in graphene/biphenylene superlattice nanoribbons: a molecular dynamic study

et al. 2022

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“…Certain studies have shown that graphene nanocomposites exhibit a relatively low percolation threshold and more optimized electrical conductivity than CNT 23 . Generally, the high surface energy of graphene and their strong interactions attenuate their uniform dispersal in the polymer medium [24][25][26][27][28] .The conductivity of nanocomposites is commonly governed by the concentration, dimensions, conductivity, and dispersion features of nanoparticles 29,30 . Many models have been developed to assume the effects of various variables, such as polymer-filler interfacial energy (affecting dispersion level), tunneling effect, agglomeration, and waviness on the conductivity of polymer nanocomposites [31][32][33][34][35][36][37] .…”

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Effect of contact resistance on the electrical conductivity of polymer graphene nanocomposites to optimize the biosensors detecting breast cancer cells

Zare

Rhee

2022

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This study focuses on the contact regions among neighboring nanoparticles in polymer graphene nanocomposites by the extension of nanosheets. The resistance of graphene and the contact zones represent the total resistance of the prolonged nanosheets. Furthermore, the graphene size, interphase depth, and tunneling distance express the effective volume portion of graphene, while the onset of percolation affects the fraction of percolated nanosheets. Finally, a model is developed to investigate the conductivity of the samples using the graphene size, interphase depth, and tunneling size. In addition to the roles played by certain factors in conductivity, the experimental conductivity data for several samples confirm the conductivity predictions. Generally, the polymer sheet in tunnels determines the total resistance of the extended nanosheets because graphene ordinarily exhibits negligible resistance. In addition, a large tunnel positively accelerates the onset of percolation, but increases the tunneling resistance and attenuates the conductivity of the nanocomposite. Further, a thicker interphase and lower percolation threshold promote the conductivity of the system. The developed model can be applied to optimize the biosensors detecting the breast cancer cells.

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Effect of Volume Fraction of Ti on Microstructure Evolution and Thermal Properties of Al/Ti Laminated Composites

Dong,

Assari,

Yaghoobi

et al. 2023

Met. Mater. Int.

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An insight into thermal properties of BC3-graphene hetero-nanosheets: a molecular dynamics study

Cited by 17 publications

References 46 publications

A theoretical insight into phonon heat transport in graphene/biphenylene superlattice nanoribbons: a molecular dynamic study

A theoretical insight into phonon heat transport in graphene/biphenylene superlattice nanoribbons: a molecular dynamic study

Effect of contact resistance on the electrical conductivity of polymer graphene nanocomposites to optimize the biosensors detecting breast cancer cells

Effect of Volume Fraction of Ti on Microstructure Evolution and Thermal Properties of Al/Ti Laminated Composites

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