Nanomaterial-embedded phase-change materials (PCMs) for reducing building cooling needs
作者: R. Parameshwaran , S. Kalaiselvam
DOI: 10.1016/B978-1-78242-380-5.00015-7
关键词: Thermal energy storage 、 Thermal 、 Thermal stability 、 Phase change 、 Materials science 、 Advanced materials 、 Nanomaterials 、 Heat transfer 、 Nanotechnology 、 Thermal conductivity
摘要: The era of nanoscience and nanotechnology has been increasingly rejuvenating the quest towards development advanced materials for cooling applications in buildings. nanomaterials being produced size range between 1 100 nm, with different surface morphologies, can be used enhancement thermal storage properties phase-change (PCMs). Nanomaterial-embedded PCMs exhibit improved conductivity, effective heat transfer, swift charging discharging rates, reduced supercooling, stability over long term. Factually, creation a densely packed network interfaces associated phonon-like transfer are expected due to infusion into PCMs. This turn facilitates their undergoing processes at relatively much faster rate compared PCM its purest form. Altogether, embedded functionalized considered potential candidates achieving needs without sacrificing energy redistribution requirements
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