2012
DOI: 10.1063/1.4728189
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Modeling and theoretical efficiency of a silicon nanowire based thermoelectric junction with area enhancement

Abstract: Recent experimental work suggests that individual silicon nanowires with rough surfaces possess a thermoelectric figure of merit as high as 0.6 near room temperature. This paper addresses the possibility of using an array of such nanowires in a thermoelectric junction for generation. Employing a model of frequency dependent phonon boundary scattering, we estimate the effective thermal conductivity of the array and investigate heat flow through the junction. We show that charge transport is largely unaffected b… Show more

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Cited by 11 publications
(6 citation statements)
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“…15−18 Differently from the phonon behavior, the electron mobility in heavily doped, few tens of nanometer wide, nanowires is only weakly affected by surface scattering, as demonstrated by theoretical analysis. 19,20 The high doping level increases the impurity scattering, reducing the electron mean free path to few nanometers (2−5 nm, depending on doping). Therefore, electron scattering due to surfaces plays its effect only within few nanometers (that is, a distance comparable with the bulk mean free path) close to the surfaces.…”
Section: Nets Of Top-down Silicon Nanowiresmentioning
confidence: 99%
See 1 more Smart Citation
“…15−18 Differently from the phonon behavior, the electron mobility in heavily doped, few tens of nanometer wide, nanowires is only weakly affected by surface scattering, as demonstrated by theoretical analysis. 19,20 The high doping level increases the impurity scattering, reducing the electron mean free path to few nanometers (2−5 nm, depending on doping). Therefore, electron scattering due to surfaces plays its effect only within few nanometers (that is, a distance comparable with the bulk mean free path) close to the surfaces.…”
Section: Nets Of Top-down Silicon Nanowiresmentioning
confidence: 99%
“…The electron mobility in a nanowire is still an open problem for nanowires narrower than 10 nm, when quantum effects begins to become important even at room temperature. , In our case, W > 50 nm so that at room temperatures we can exclude important quantum effect; modification of electron mobility can also derive from the surface scattering. Several works measured the SiNW electron mobility by different techniques. Differently from the phonon behavior, the electron mobility in heavily doped, few tens of nanometer wide, nanowires is only weakly affected by surface scattering, as demonstrated by theoretical analysis. , The high doping level increases the impurity scattering, reducing the electron mean free path to few nanometers (2–5 nm, depending on doping). Therefore, electron scattering due to surfaces plays its effect only within few nanometers (that is, a distance comparable with the bulk mean free path) close to the surfaces .…”
Section: Nets Of Top-down Silicon Nanowiresmentioning
confidence: 99%
“…4 for the Seebeck coefficient. We use results from our previous work on scattering rates for electrons and holes 20,27 to calculate the electrical conductivity. From our calculations, the optimal doping is in the range 4-6 × 10 19 cm −3 across doping polarities.…”
Section: Discussionmentioning
confidence: 99%
“…In this case, MFP in bulk is in the order of 2-5 nm, implying that significant σ reduction takes place only when the diameter of the nanowire is reduced below this threshold. This issue has been theoretically discussed by Seong et al and Shi et al [90,91] but, so far, there is no experimental evidence of carrier scattering at nanowire boundaries affecting thermoelectric properties.…”
Section: Surface Roughness Enhanced Phonon Scatteringmentioning
confidence: 98%