Journal
ENERGY REPORTS
Volume 7, Issue -, Pages 87-96Publisher
ELSEVIER
DOI: 10.1016/j.egyr.2021.02.049
Keywords
Solar thermal collectors; Thermal storage; Silver nanoparticles; Nanofluids; Stability
Categories
Funding
- Faculty of Engineering and Physical Sciences at the University of Southampton, UK
- Engineering and Physical Sciences Research Council (EPSRC), UK through the Centre for Doctoral Training in Energy Storage and its Applications at the University of Southampton [EP/L016818/1]
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This study investigated the synthesis and temperature stability testing of three silver-based nanofluids for enhanced efficiency volumetric solar-thermal collectors. Results indicate the need for an appropriate stabilization strategy for a broadband absorber based on silver.
This paper details an investigation into the synthesis and temperature stability testing of silver-nanofluids, aimed at producing three silver-based nanofluids with distinctive morphologies and absorption characteristics suitable for enhanced efficiency volumetric solar-thermal collectors, which could be combined with a suitable thermal storage system to provide low-carbon heating and hot-water. When combined the three silver-based nanofluids were designed to give spectrally broadband absorption of the incident solar radiation in the 300-1300 nm range. The starting point was a previously developed synthesis producing triangular silver-nanoparticles with a strong absorbance in the 850-950 nm range (Nanofluid 1). The effect of changing various reagents in the synthesis was then investigated. Increasing the silver nitrate concentration and changing the silver to reducing agent ratio produced Nanofluid 2 (strong absorbance in 650-750 nm range), containing smaller more rounded triangular nanoparticles. For Nanofluid 3, a two-step synthesis had to be adopted, with a seed nanofluid made initially by lowering the concentration of reducing agent (sodium borohydride) and oxidizing agent (hydrogen peroxide). Additional silver nitrate and reducing agent were added, giving a more concentrated nanofluid, containing small silver nanodiscs, with a 450 nm absorption maximum. These three nanofluids were combined together to give a broadband absorber and for the first time, the stability to a temperature of 70 degrees C measured using UV-vis-IR spectroscopy. Results indicate that although a broadband absorber based on silver can be designed it is not suitable for use without an appropriate stabilization strategy, due to a lack of spectral stability with temperature. (C) 2021 The Author(s). Published by Elsevier Ltd.
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