Role of light and heavy embedded nanoparticles on the thermal conductivity of SiGe alloys

Role of light and heavy embedded nanoparticles on the thermal conductivity of SiGe alloys

We have used an atomistic ab initio approach with no adjustable parameters to compute the lattice thermal conductivity of Si0.5Ge0.5 with a low concentration of embedded Si or Ge nanoparticles of diameters up to 4.4 nm. Through exact Green's function calculation of the nanoparticle scattering rates, we find that embedding Ge nanoparticles in Si0.5Ge0.5 provides 20% lower thermal conductivities than embedding Si nanoparticles. This contrasts with the Born approximation, which predicts an equal amount of reduction for the two cases, irrespective of the sign of the mass difference. Despite these differences, we find that the Born approximation still performs remarkably well, and it permits investigation of larger nanoparticle sizes, up to 60 nm, not feasible with the exact approach.

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Bibliographic Details
Main Authors: Kundu, Anupam, Mingo, Natalio, Broido, David, Stewart, Derek
Format: article biblioteca
Language:en_US
Published: American Physical Society 2011-09-09
Subjects:SiGe alloy, thermal conductivity, heat transfer, nanoparticle, density functional theory, thermoelectric, Born approximation, Green's function,
Online Access:https://hdl.handle.net/1813/23577
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Summary:We have used an atomistic ab initio approach with no adjustable parameters to compute the lattice thermal conductivity of Si0.5Ge0.5 with a low concentration of embedded Si or Ge nanoparticles of diameters up to 4.4 nm. Through exact Green's function calculation of the nanoparticle scattering rates, we find that embedding Ge nanoparticles in Si0.5Ge0.5 provides 20% lower thermal conductivities than embedding Si nanoparticles. This contrasts with the Born approximation, which predicts an equal amount of reduction for the two cases, irrespective of the sign of the mass difference. Despite these differences, we find that the Born approximation still performs remarkably well, and it permits investigation of larger nanoparticle sizes, up to 60 nm, not feasible with the exact approach.

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