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Photo-thermal conversion properties of MXene/metal-organic-frameworks-based nanofluids for solar energy harvesting

Seyedeh Zahra Haeri, Ali Dashan, Samira Sadeghi, Mitra Golgoli, Mehdi Khiadani, Bahram Ramezanzadeh, Masoumeh Zargar

2024Journal of Colloid and Interface Science20 citationsDOIOpen Access PDF

Abstract

• MXene/NH 2 -UiO66 and MXene/MIL-88B-Fe hybrid nanofluids were successfully prepared. • The MXene/NH 2 -UiO66 hybrid nanofluid exhibited the highest light absorption. • The MXene/MIL-88B hybrid nanofluid showed the highest thermal conductivity. • 85 % photothermal conversion efficiency was achieved with MXene/NH 2 -UiO66 nanofluid. This study focuses on enhancing solar energy capture efficiency by introducing innovative hybrid nanofluids for use in solar thermal collectors, whose performance largely depends on the absorption properties of the working fluid. The newly developed hybrid nanofluids, MXene/NH2-UiO66 (Zr) (noted as MX/UO66) and MXene/MIL-88B (Fe) (noted as MX/ML88), were synthesized using an in-situ solvothermal method, combining annealed Ti3C2Tx MXenes with water-stable metal–organic frameworks (MOFs). These nanofluids achieved high efficiency at low concentrations, providing both economic and performance benefits. Comprehensive testing compared the photothermal properties of these hybrids with single-component UO66 and ML88 nanofluids. The MX structures significantly expanded the absorption range and intensity for UO66 and ML88, with MXUO66 and MXML88 displaying superior thermal conductivity and light absorption compared to single-component fluids. At a concentration of 220 ppm, MXUO66 and MXML88 achieved photothermal efficiencies of 85 % and 79 %, respectively, improving by 24.5 % and 11.3 % over UO66 and ML88 alone. Results indicate that the MX-UO66 combination is particularly effective, demonstrating the strong potential of these composites for optimizing solar energy systems. This work highlights the capability of nanoporous materials with enhanced photothermal properties, underscoring their adaptability for various solar applications and the importance of optimizing collector designs to minimize heat losses.

Topics & Concepts

NanofluidThermalChemical engineeringMetal-organic frameworkMaterials scienceEnergy transformationSolar energyMetalNanotechnologyChemistryNanoparticleOrganic chemistryMetallurgyThermodynamicsAdsorptionPhysicsEcologyBiologyEngineeringMXene and MAX Phase MaterialsSolar-Powered Water Purification MethodsEnergy Harvesting in Wireless Networks
Photo-thermal conversion properties of MXene/metal-organic-frameworks-based nanofluids for solar energy harvesting | Litcius