Luca Mercatelli scite author profile

The optimization of the poor heat transfer characteristics of fluids conventionally employed in solar devices are at present one of the main topics for system efficiency and compactness. In the present work we investigated the optical and thermal properties of nanofluids consisting in aqueous suspensions of single wall carbon nanohorns. The characteristics of these nanofluids were evaluated in view of their use as sunlight absorber fluids in a solar device. The observed nanoparticle-induced differences in optical properties appeared promising, leading to a considerably higher sunlight absorption. We found that the thermal conductivity of the nanofluids was higher than pure water. Both these effects, together with the possible chemical functionalization of carbon nanohorns, make this new kind of nanofluids very interesting for increasing the overall efficiency of the sunlight exploiting device.

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Potential of carbon nanohorn-based suspensions for solar thermal collectors

Sani

Mercatelli

Barison

et al. 2011

Solar Energy Materials and Solar Cells

194

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Absorption and scattering properties of carbon nanohorn-based nanofluids for direct sunlight absorbers

et al. 2011

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In the present work, we investigated the scattering and spectrally resolved absorption properties of nanofluids consisting in aqueous and glycol suspensions of single-wall carbon nanohorns. The characteristics of these nanofluids were evaluated in view of their use as sunlight absorber fluids in a solar device. The observed nanoparticle-induced differences in optical properties appeared promising, leading to a considerably higher sunlight absorption with respect to the pure base fluids. Scattered light was found to be not more than about 5% with respect to the total attenuation of light. Both these effects, together with the possible chemical functionalization of carbon nanohorns, make this new kind of nanofluids very interesting for increasing the overall efficiency of the sunlight exploiting device.PACS78.40.Ri, 78.35.+c, 78.67.Bf, 88.40.fh, 88.40.fr, 81.05.U.

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Suitability of ultra-refractory diboride ceramics as absorbers for solar energy applications

Sciti

Silvestroni

Mercatelli

et al. 2013

Solar Energy Materials and Solar Cells

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Ultra-refractory ceramics for high-temperature solar absorbers

et al. 2011

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Luca Mercatelli

Carbon nanohorns-based nanofluids as direct sunlight absorbers

Potential of carbon nanohorn-based suspensions for solar thermal collectors

Absorption and scattering properties of carbon nanohorn-based nanofluids for direct sunlight absorbers

Suitability of ultra-refractory diboride ceramics as absorbers for solar energy applications

Ultra-refractory ceramics for high-temperature solar absorbers

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