Photo-thermal conversion properties of hybrid NH2-MIL-125/TiN/EG nanofluids for solar energy harvesting

[Display omitted] •NH2-MIL-125/TiN/EG hybridnanofluidswere prepared.•NH2-MIL-125nanoparticlesimproved the photothermal stability of TiNnanofluids.•The final composite nanofluid can realise both outstanding photothermal properties and stability.•A photothermal conversion efficiency of 83 % is achieva...

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Published in:Applied thermal engineering 2025-01, Vol.258, p.124607, Article 124607
Main Authors: Zahra Haeri, Seyedeh, Khiadani, Mehdi, Ramezanzadeh, Bahram, Kariman, Hamed, Zargar, Masoumeh
Format: Article
Language:English
Subjects:
Composite nanofluids
Direct solar thermal energy harvest
NH2-MIL-125 (Ti) metal–organic frameworks, photothermal efficiency
Temperature distribution of nanofluids
Titanium nitride
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Summary:[Display omitted] •NH2-MIL-125/TiN/EG hybridnanofluidswere prepared.•NH2-MIL-125nanoparticlesimproved the photothermal stability of TiNnanofluids.•The final composite nanofluid can realise both outstanding photothermal properties and stability.•A photothermal conversion efficiency of 83 % is achievable for 60 ppm MIL/TiN (M5:T5) nanofluid. Nanofluids, engineered by dispersing nanoparticles into base fluids, have demonstrated significant potential in enhancing the performance of solar collectors. Their superior thermal conductivity and improved heat transfer properties lead to more efficient energy absorption and utilization in solar thermal systems. This study comprehensively investigated and compared the performance of ethylene glycol (EG)-based NH2-MIL-125/TiN (MIL/TiN) composite nanofluids, fabricated by a two-step method, with single-component nanofluids in photothermal utilization. The results illustrated that incorporating NH2-MIL-125 (MIL) nanoparticles enhances the stability of TiN nanofluids in EG. Additionally, the thermal conductivity and optical absorption properties of the hybrid nanofluids exhibited a positive correlation with the proportion of TiN nanoparticles. The results showed that hybrid nanofluids demonstrate excellent solar radiation absorption across a broad spectrum from UV to NIR, with minimal heat loss and significant depth penetration. The MIL/TiN (M5) hybrid nanofluid achieved a remarkable photothermal conversion efficiency of 83 %, outperforming that of single TiN and MIL-125(Ti) nanofluids by 19 % and 15 %, respectively. Furthermore, the efficiency distribution within the collector reached 100 % at a height of 3.5 cm with this hybrid MIL/TiN nanofluid, even at a low concentration of 20 ppm. This research highlights a promising nanofluid that can enhance photothermal conversion efficiency in solar thermal systems. It leverages the capabilities of nanoporous materials with superior photothermal properties and optimizes the structural design of solar collectors to minimize heat losses, making it suitable for various applications.
ISSN:1359-4311
DOI:10.1016/j.applthermaleng.2024.124607