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Optical and Transport Properties of Metal–Oil Nanofluids for Thermal Solar Industry: Experimental Characterization, Performance Assessment, and Molecular Dynamics Insights

Iván Carrillo‐Berdugo, Patrice Estellé, Elisa Sani, Luca Mercatelli, Ricardo Grau‐Crespo, David Zorrilla, Javier Navas

2021ACS Sustainable Chemistry & Engineering17 citationsDOIOpen Access PDF

Abstract

Concentrating solar power (CSP) technology can become a very valuable contributor to the transformation and decarbonization of our energy landscape, but for this technology to overcome the barrier toward market deployment, significant enhancements in the solar-to-thermal-to-electric energy conversion efficiency are needed. Here, an in-depth experimental analysis of the optical and transport properties of Pd-containing aromatic oil-based nanofluids is presented, with promising results for their prospective use as volumetric absorbers and heat transfer fluids in next-generation parabolic-trough CSP plants. A 0.030 wt % concentration of Pd nanoplates increases sunlight extinction by 90% after 20 mm propagation length and thermal conductivity by 23.5% at 373 K, which is enough to increase the overall system efficiency up to 45.3% and to reduce pumping requirements by 20%, with minimum increases in the collector length. In addition to that, molecular dynamics simulations are used to gain atomistic-level insights about the heat and momentum transfer in these nanofluids, with a focus on the role played by the solid–liquid interface in these phenomena. Molecules chemisorbed at the interface behave as a shelter-like boundary that hinders heat conduction, as a high thermal resistance path, and minimizes the impact of the solid on dynamic viscosity, as it weakens the interactions between the nanoplate and the surrounding nonadsorbed fluid molecules.

Topics & Concepts

NanofluidMaterials scienceThermal conductivityHeat transferParabolic troughSolar energyThermal conductionThermalThermal fluidsEnergy conversion efficiencyChemical physicsNanofluidicsThermal energy storageNanotechnologyConcentrated solar powerThermal energyNanofluids in solar collectorsViscosityThermodynamicsThermal resistanceNanoparticleComposite materialChemistryOptoelectronicsPhotovoltaic thermal hybrid solar collectorBiologyPhysicsEcologyNanofluid Flow and Heat TransferSolar Thermal and Photovoltaic SystemsSolar-Powered Water Purification Methods
Optical and Transport Properties of Metal–Oil Nanofluids for Thermal Solar Industry: Experimental Characterization, Performance Assessment, and Molecular Dynamics Insights | Litcius