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Techno-Economic Analysis and Assessment of an Innovative Solar Hybrid Photovoltaic Thermal Collector for Transient Net Zero Emissions

Abdelhakim Hassabou, Sadiq H. Melhim, Rima J. Isaifan

2025Sustainability10 citationsDOIOpen Access PDF

Abstract

Achieving net-zero emissions in arid and high-solar-yield regions demands innovative, cost-effective, and scalable energy technologies. This study conducts a comprehensive techno-economic analysis and assessment of a novel hybrid photovoltaic–thermal solar collector (U.S. Patent No. 11,431,289) that integrates a reverse flat plate collector and mini-concentrating solar thermal elements. The system was tested in Qatar and Germany and simulated via a System Advising Model tool with typical meteorological year data. The system demonstrated a combined efficiency exceeding 90%, delivering both electricity and thermal energy at temperatures up to 170 °C and pressures up to 10 bars. Compared to conventional photovoltaic–thermal systems capped below 80 °C, the system achieves a heat-to-power ratio of 6:1, offering an exceptional exergy performance and broader industrial applications. A comparative financial analysis of 120 MW utility-scale configurations shows that the PVT + ORC option yields a Levelized Cost of Energy of $44/MWh, significantly outperforming PV + CSP ($82.8/MWh) and PV + BESS ($132.3/MWh). In addition, the capital expenditure is reduced by over 50%, and the system requires 40–60% less land, offering a transformative solution for off-grid data centers, water desalination (producing up to 300,000 m3/day using MED), district cooling, and industrial process heat. The energy payback time is shortened to less than 4.5 years, with lifecycle CO2 savings of up to 1.8 tons/MWh. Additionally, the integration with Organic Rankine Cycle (ORC) systems ensures 24/7 dispatchable power without reliance on batteries or molten salt. Positioned as a next-generation solar platform, the Hassabou system presents a climate-resilient, modular, and economical alternative to current hybrid solar technologies. This work advances the deployment readiness of integrated solar-thermal technologies aligned with national decarbonization strategies across MENA and Sub-Saharan Africa, addressing urgent needs for energy security, water access, and industrial decarbonization.

Topics & Concepts

Photovoltaic systemPayback periodOrganic Rankine cycleProcess engineeringCost of electricity by sourceHybrid systemSolar thermal collectorPhotovoltaic thermal hybrid solar collectorRenewable energyEnvironmental scienceExergyExergy efficiencySolar energyDispatchable generationElectricityAutomotive engineeringConcentrated solar powerEngineeringRankine cycleThermalThermal energyElectricity generationDesalinationThermal efficiencyTransient (computer programming)Net present valueSolar powerCapital costParabolic troughThermal energy storageEnvironmental engineeringThermal power stationDegree RankineWaste managementSystem integrationPower (physics)Mechanical engineeringHybrid powerElectric power systemEnergy storageSolar Thermal and Photovoltaic SystemsThermodynamic and Exergetic Analyses of Power and Cooling SystemsThermal Radiation and Cooling Technologies