24 research outputs found

    Anisotropic intrinsic lattice thermal conductivity of phosphorene from first principles

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    Phosphorene, the single layer counterpart of black phosphorus, is a novel two-dimensional semiconductor with high carrier mobility and a large fundamental direct band gap, which has attracted tremendous interest recently. Its potential applications in nano-electronics and thermoelectrics call for a fundamental study of the phonon transport. Here, we calculate the intrinsic lattice thermal conductivity of phosphorene by solving the phonon Boltzmann transport equation (BTE) based on first-principles calculations. The thermal conductivity of phosphorene at 300 K300\,\mathrm{K} is 30.15 Wm−1K−130.15\,\mathrm{Wm^{-1}K^{-1}} (zigzag) and 13.65 Wm−1K−113.65\,\mathrm{Wm^{-1}K^{-1}} (armchair), showing an obvious anisotropy along different directions. The calculated thermal conductivity fits perfectly to the inverse relation with temperature when the temperature is higher than Debye temperature (ΘD=278.66 K\Theta_D = 278.66\,\mathrm{K}). In comparison to graphene, the minor contribution around 5%5\% of the ZA mode is responsible for the low thermal conductivity of phosphorene. In addition, the representative mean free path (MFP), a critical size for phonon transport, is also obtained.Comment: 5 pages and 6 figures, Supplemental Material available as http://www.rsc.org/suppdata/cp/c4/c4cp04858j/c4cp04858j1.pd

    An analysis of programs by algebraic means

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    An approximate mathematical model of heat and mass transfer in two-phase flow

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    Programs and logics

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    Queue machines: An organization for parallel computation

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    Controlled grammatic ambiguity

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