Near-Field Thermal Transistor

Ben‐Abdallah, Philippe; Biehs, Svend‐Age

doi:10.1103/physrevlett.112.044301

Cited by 462 publications

(377 citation statements)

References 21 publications

(23 reference statements)

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“…[7][8][9][10][11][12] Due to the heat transfer in graphene mainly contributed by phonons, [5] the thermal conductivity of graphene can be manipulated by the management of phonons.…”

Section: Introductionmentioning

confidence: 99%

Manipulating the temperature dependence of the thermal conductivity of graphene phononic crystal

Yang

et al. 2016

Nanotechnology

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By using non-equilibrium molecular dynamics simulations (NEMD), the modulation on temperature dependence of thermal conductivity of graphene phononic crystals (GPnCs) are investigated. It is found that the temperature dependence of thermal conductivity of GPnCs follows ~ T -α behavior. The power exponents (α) can be efficiently tuned by changing the characteristic size of GPnCs. The phonon participation ratio spectra and dispersion relation reveal that the long-range phonon modes are more affected in GPnCs with larger size of holes (L0). Our results suggest that constructing GPnCs is an effective method to manipulate the temperature dependence of thermal conductivity of graphene, which would be beneficial for developing GPnCs-based thermal management and signal processing devices.

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“…[7][8][9][10][11][12] Due to the heat transfer in graphene mainly contributed by phonons, [5] the thermal conductivity of graphene can be manipulated by the management of phonons.…”

Section: Introductionmentioning

confidence: 99%

Manipulating the temperature dependence of the thermal conductivity of graphene phononic crystal

Yang

et al. 2016

Nanotechnology

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“…Examples of these features include that: i) the thermal conductivity could deviate from Fourier's law [1][2][3][4][5], ii) a crossover is observed from ballistic into diffusive transport regimes [6,7], or from nanoto macro-scale behaviors [8,9], iii) the thermal conductivity could even increase under channel width confinement [10,11], iv) band mismatch under extreme confinement could result to phonon localization and 'effective transmission bandgaps' [12], v) heat transport could be below the Casimir or the amorphous limits, and many more [13,14]. Several interesting device concepts have also emerged recently in the area of phononics, which attempt to use heat to perform transistor action [15], create heat rectifiers [16], engineer the sound velocities and phonon dispersions, etc. [13,17,18].…”

Section: Introductionmentioning

confidence: 99%

Phonon transport effects in one-dimensional width-modulated graphene nanoribbons

Karamitaheri

Neophytou

2016

Journal of Applied Physics

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We investigate the thermal conductance of one-dimensional periodic widthmodulated graphene nanoribbons using lattice dynamics for the phonon spectrum and the Landauer formalism for phonon transport. We conduct a full investigation considering all relevant geometrical features, i.e. the various lengths and widths of the narrow and wide regions that form the channel. In all cases that we examine, we find that widthmodulation suppresses the thermal conductance at values even up to ~70 % below those of the corresponding uniform narrow nanoribbon. We show that this can be explained by the fact that the phonon spectrum of the width-modulated channels acquires less dispersive bands with lower group velocities and several narrow bandgaps, which reduce the phonon transmission function significantly. The largest degradation in thermal conductance is determined by the geometry of the narrow regions. The geometry of the wider regions also influences thermal conductance, although modestly. Our results add to the ongoing efforts in understanding the details of phonon transport at the nanoscale, and our conclusions are generic and could also apply to other one-dimensional channel materials.

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“…This fact has inspired researchers to generate similar techniques for controlling the near-field thermal transfer similar to the ones that have been developed for controlling thermal emission [5][6][7][8] . Such efforts have lead to the design of nanostructures for a variety of applications such as thermal rectifiers 9 , thermal diodes 10 , and near-field thermal transistors 11 .…”

Section: Introductionmentioning

confidence: 99%

Effect of shape in near-field thermal transfer for periodic structures

2015

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In this paper, the effect of the geometrical shape on the radiative thermal transfer between a periodic array of beams and a planar substrate is investigated. Specifically, we analyze the changes in the thermal transfer that occur when the cross sectional shape of SiC beams is modified from rectangular to ellipsoidal and finally triangular. Numerical calculations are done based on the rigorous coupled wave analysis. These exact results from this analysis are compared to modified proximity and far-field approximations, which become valid for small and large spacings, respectively. Moreover, these results are also compared to effective medium theory, which becomes increasingly accurate in the limit of small periodicities. We show that a reduction in the periodicity will lead to a reduced thermal transfer for triangular and ellipsoidal shaped beams. Even though, in the limit of very small periodicity, thermal transfer for the case of rectangular shaped beams also decreases by decreasing the periodicity but this decrease is more slowly as compared to other cross sectional shapes. Finally, we show that even though changing periodicity will change the magnitude of thermal transfer, the scaling law for its variation with the beam to substrate spacing is primarily determined by the cross sectional shape rather than the periodicity. We analytically prove this fact by investigating the large and small periodicity regimes. INTRODUCTION:

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Near-Field Thermal Transistor

Cited by 462 publications

References 21 publications

Manipulating the temperature dependence of the thermal conductivity of graphene phononic crystal

Manipulating the temperature dependence of the thermal conductivity of graphene phononic crystal

Phonon transport effects in one-dimensional width-modulated graphene nanoribbons

Effect of shape in near-field thermal transfer for periodic structures

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