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MXene-based hybrid nanofluids in pulsating heat pipes: Advanced thermal management for photovoltaic efficiency enhancement and economic analysis

Mahyar Kargaran, Saeed Zeinali Heris, Seyed Borhan Mousavi, Saeed Azarberahman

2025Energy9 citationsDOIOpen Access PDF

Abstract

Efficient thermal management remains a critical limitation for photovoltaic (PV) panels operating under high solar irradiance, where temperature rises can reduce electrical efficiency by up to 0.5% per °C. This study introduces and experimentally validates, for the first time, a dual pulsating heat pipe (PHP) cooling system employing eco-friendly MXene-based hybrid nanofluids, specifically MXene–reduced graphene oxide (MXene-rGO) and MXene–copper oxide (MXene-CuO), as advanced working media. Outdoor experiments evaluated thermal, electrical, exergy, and economic performance at low nanoparticle concentrations (0.1 and 0.2 wt.%). At 0.2 wt.%, MXene-rGO enhanced PV electrical efficiency by 12.1%, exergy efficiency by 7.6%, and reduced thermal resistance by 44% relative to an uncooled panel. MXene-CuO achieved corresponding improvements of 8.6% and 4.8%, confirming strong heat transfer synergy between MXene and metal or carbon components. Economic evaluation demonstrated long-term feasibility, with a levelized cost of energy (LCOE) of 0.107 $/kWh and a net present value (NPV) of $287, indicating a favorable cost–performance balance. The proposed MXene-based PHP concept establishes a new pathway for passive and sustainable PV thermal management, offering the first integrated experimental, exergy, and techno-economic assessment of hybrid nanofluid cooling for real outdoor PV operation. • MXene-based nanofluids enhance PV cooling via pulsating heat pipes. • MXene-CuO (0.2 wt.%) boosts PV efficiency by 8.58%, MXene-rGO by 12.06%. • MXene-rGO (0.2 wt.%) increases exergy efficiency by 7.63%, MXene-CuO by 4.75% • MXene-CuO (0.2 wt.%) reduces PV thermal resistance by 32.98%, MXene-rGO by 46.94%. • MXene-CuO and MXene-rGO nanofluids boost long-term PV performance and savings.

Topics & Concepts

NanofluidPhotovoltaic systemMaterials scienceExergyExergy efficiencyNanofluids in solar collectorsThermal efficiencyHeat transferThermalPassive coolingPhotovoltaic thermal hybrid solar collectorEnvironmental scienceOxideEnergy conversion efficiencyThermal management of electronic devices and systemsSolar energyProcess engineeringNuclear engineeringWater coolingThermal resistanceGrapheneThermal energyElectrical efficiencyCost of electricity by sourceEfficient energy useMechanical engineeringConcentrated solar powerRenewable energyThermal conductivityElectricity generationEnergy transformationPhase-change materialSolar-Powered Water Purification MethodsSolar Thermal and Photovoltaic SystemsThermal properties of materials