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Next-generation solar technologies: Unlocking the potential of Ag-ZnO hybrid nanofluids for enhanced spectral-splitting photovoltaic-thermal systems

Sandesh S. Chougule, Abhishek Srivastava, Gaurav G. Bolegave, Bhagyashree A. Gaikwad, Parasharam M. Shirage, Christos N. Markides

2024Renewable Energy56 citationsDOIOpen Access PDF

Abstract

In traditional hybrid concentrating photovoltaic-thermal (PV-T) collectors, suboptimal utilisation of the solar spectrum results in elevated temperatures that adversely affect PV cell efficiency. In this context, solar spectral beam splitting (SBS) designs have emerged as they promise improved solar spectrum utilisation with reduced optical losses. In particular, fluid-based SBS filters, such as novel Ag-ZnO/water hybrid nanofluids, have attracted attention as they present a significant advantage over conventional filters (e.g., anti-reflective coatings, selective coatings, bandpass filters, long-pass/short-pass filters, dielectric filters). These nanofluid filters serve as both heat transfer and thermal storage mediums, enhancing the overall efficiency of PV-T systems. Full-spectrum solar utilisation via SBS enables down conversion in the UV region, transmission of visible and near-infrared light (crucial for Si PV cell optoelectronic efficiency), and absorption of the infrared region. A Ag-ZnO/water nanofluid filter-based PV-T system is investigated and is shown to achieve a thermal efficiency > 65 % with good electrical performance. Optimal conditions include an Ag-ZnO concentration of 50 ppm, solar irradiance of 800–1000 W/m 2 , and optical thickness of 20 mm. The integration of this type of nanofluid filter enhances spectral selectivity, reduces PV cell temperatures, improves heat extraction, and offers dual functionality: cooling and filtration, making it a promising and economically viable candidate for commercial PV-T applications. Schematics representing the typical synthesis of the Ag-ZnO nanoparticle, PV-T design, and obtained electrical and thermal efficiencies with varying concentrations, solar irradiance, and optical thicknesses. • The performance of an Ag-ZnO/water nanofluid filter-based PV-T system is studied. • The optimum concentration, G , and d OT is 50 ppm, 800–1000 W/m 2 , and 20 mm. • Most importantly, the η t is dominated by η th , and η el remains nearly constant. • Spectral selectivity, economic viability, and sustainability are the key novelties. • Average 44 % lesser PP PV-T as compared to gold (Au) and Polypyrrole (Ppy) PV-T spectral splitter.

Topics & Concepts

NanofluidPhotovoltaic systemThermalMaterials scienceOptoelectronicsEngineering physicsNanotechnologyEngineeringElectrical engineeringPhysicsNanoparticleThermodynamicsSolar Thermal and Photovoltaic SystemsPhotovoltaic System Optimization Techniquessolar cell performance optimization