Abstract
By way of the non-equilibrium Green’s function simulations and first-principles calculations, we report that borophene, a single layer of boron atoms that was fabricated recently, possesses an extraordinarily high lattice thermal conductance in the ballistic transport regime, which even exceeds graphene. In addition to the obvious reasons of light mass and strong bonding of boron atoms, the superior thermal conductance is mainly rooted in its strong structural anisotropy and unusual phonon transmission. For low-frequency phonons, the phonon transmission within borophene is nearly isotropic, similar to that of graphene. For high-frequency phonons, however, the transmission is one-dimensional, that is, all the phonons travel in one direction, giving rise to its ultra-high thermal conductance. The present study suggests that borophene is promising for applications in efficient heat dissipation and thermal management, and also an ideal material for revealing fundamentals of dimensionality effect on phonon transport in ballistic regime.
Highlights
Thermal transport is known to be one of the major forms of energy transfer in nature
By using first-principles calculations and nonequilibrium Green’s function (NEGF) technique, we investigate the lattice thermal transport properties of borophene for both hexagonal model and β12 model
The strong covalent bonding in borophene suggests that it has a high Debye temperature.[41]
Summary
Thermal transport is known to be one of the major forms of energy transfer in nature. B Phonon dispersion and density of states of borophene the quantum thermal conductance in the x-direction is 55% larger than that of graphene.
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