Thermal conductivity and spectral phonon properties of freestanding and supported silicene

Wang, Zuyuan; Feng, Tianli; Ruan, Xiulin

doi:10.1063/1.4913600

Cited by 76 publications

(66 citation statements)

References 58 publications

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“…For instance, the thermal conductivity of ASNT and ZSNT decreases by about 50% when the temperature increases from 300-550 K while it decreases 18% in the temperature growth from 550-700 K. We notice that the thermal conductivity of silicene nanotubes versus temperature is not sensitive to chirality thus the MD results obtained for ASNT and ZSNT are the same. Our findings are in agreement with previously research reported on the temperature dependence of the thermal conductivity of bulk silicene and silicene nanosheets [47,49]. Studying the thermal properties of silicene nanotubes under extreme condition such as defects and strain is essential for practical applications.…”

Section: Resultssupporting

confidence: 93%

“…In semimetals, such as silicene, the contribution of electrons on the thermal conductivity at room temperature and above is less than that of phonons. Therefore, non-equilibrium molecular dynamics (NEMD) simulation that ignores electron transport can be used to investigate the thermal properties of silicene [47]. In this research, the non-equilibrium molecular dynamics (NEMD) simulation is carried out using Large-scale Atomic/Molecular Massively Parallel Simulator (LAMMPS) [48] to study the effect of the grain boundary, axial strain, random vacancy defect, and temperature on the thermal conductivity of silicene nanotubes.…”

Section: Model and Simulation Methodsmentioning

confidence: 99%

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Thermal transport in silicene nanotubes: Effects of length, grain boundary and strain

Khalkhali

Khoeini

Rajabpour

2019

International Journal of Heat and Mass Transfer

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Thermal transport behavior in silicene nanotubes has become more important due to the application of these promising nanostructures in the engineering of next-generation nanoelectronic devices. We apply non-equilibrium molecular dynamics (NEMD) simulations to study the thermal conductivity of silicene nanotubes with different lengths and diameters. We further explore the effects of grain boundary, strain, vacancy defect, and temperature in the range of 300-700 K on the thermal conductivity. Our results indicate that the thermal conductivity varies with the length approximately in the range of 24-34 W/m.K but exhibits insensitivity to the diameter and chirality. Besides, silicene nanotubes consisting of the grain boundary exhibit nearly 30% lower thermal conductivity compared with pristine ones. We discuss the underlying mechanism for the conductivity suppression of the system consisting of the grain boundary by calculating the phonon power spectral density. We find that by increasing the defect concentration and temperature, the thermal conductivity of the system decreases desirably. Moreover, for strained nanotubes, we observe unexpected changes in the thermal conductivity, so that the conductivity first increases significantly with tensile strain and then starts to decrease. The maximum thermal conductivity for the armchair and zigzag edge tubes appears at the strains about 3% and 5%, respectively, which is about 28% more than that of the unstrained structure.

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Section: Resultssupporting

confidence: 93%

Section: Model and Simulation Methodsmentioning

confidence: 99%

Thermal transport in silicene nanotubes: Effects of length, grain boundary and strain

Khalkhali

Khoeini

Rajabpour

2019

International Journal of Heat and Mass Transfer

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“…Unlike graphene in which all carbon atoms form honey-cone structures within a flat plane, silicon atoms in silicone show a buckled structure, resulting in unique thermal transports fundamentally differing from that in other 2D materials, namely (a) longitudinal and transverse acoustic phonons dominate the thermal transports and the acoustic out-of-plane phonon modes only have less than 10% contributions to the total thermal conductivity [114][115][116][117]; (b) thermal conductivity increases dramatically with tensile strain due to enhancement in acoustic phonon lifetime [118][119][120]. Unfortunately, no experiment on thermal conductivity in silicene has been reported.…”

Section: Silicenementioning

confidence: 99%

Phonon thermal conduction in novel 2D materials

Chen

2016

J. Phys.: Condens. Matter

101

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Recently, there have been increasing interests in phonon thermal transport in low dimensional materials, due to the crucial importance for dissipating and managing heat in micro and nano electronic devices. Significant progresses have been achieved for one-dimensional (1D) systems both theoretically and experimentally. However, the study of heat conduction in two-dimensional (2D) systems is still in its infancy due to the limited availability of 2D materials and the technical challenges in fabricating suspended samples suitable for thermal measurements. In this review, we outline different experimental techniques and theoretical approaches for phonon thermal transport in 2D materials, discuss the problems and challenges in phonon thermal transport measurements and provide comparison between existing experimental data. Special focus will be given to the effects of the size, dimensionality, anisotropy and mode contributions in the novel 2D systems including graphene, boron nitride, MoS 2 , black phosphorous, silicene etc.

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“…Wang et al, 13 Li et al 5 and Hu et al 2 employed the Tersoff potential to investigate the thermal conductivity of free-standing and supported single layer silicene. Tersoff potential 12 has been widely used to describe the Si atom interactions in bulk silicon and silicon nanotubes.…”

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confidence: 99%

Molecular dynamics study of interfacial thermal transport between silicene and substrates

Zhang

Yang

Tong

et al. 2015

Phys. Chem. Chem. Phys.

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In this work, the interfacial thermal transport across silicene and various substrates, i.e., crystalline silicon (c-Si), amorphous silicon (a-Si), crystalline silica (c-SiO2) and amorphous silica (a-SiO2) are explored by classical molecular dynamics (MD) simulations. A transient pulsed heating technique is applied in this work to characterize the interfacial thermal resistance in all hybrid systems. It is reported that the interfacial thermal resistances between silicene and all substrates decrease nearly 40% with temperature from 100 K to 400 K, which is due to the enhanced phonon couplings from the anharmonicity effect. Analysis of phonon power spectra of all systems is performed to interpret simulation results. Contradictory to the traditional thought that amorphous structures tend to have poor thermal transport capabilities due to the disordered atomic configurations, it is calculated that amorphous silicon and silica substrates facilitate the interfacial thermal transport compared with their crystalline structures. Besides, the coupling effect from substrates can improve the interface thermal transport up to 43.5% for coupling strengths χ from 1.0 to 2.0. Our results provide fundamental knowledge and rational guidelines for the design and development of the next-generation silicene-based nanoelectronics and thermal interface materials.

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Thermal conductivity and spectral phonon properties of freestanding and supported silicene

Cited by 76 publications

References 58 publications

Thermal transport in silicene nanotubes: Effects of length, grain boundary and strain

Thermal transport in silicene nanotubes: Effects of length, grain boundary and strain

Phonon thermal conduction in novel 2D materials

Molecular dynamics study of interfacial thermal transport between silicene and substrates

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