Recent innovations in nano-enhanced phase change materials (PCMs), hybrid TES configurations, and intelligent system integration are highlighted. The role of advanced computational
We delve into the various ways nanomaterials are being integrated into different energy storage systems, including a range of battery technologies such as lithium-ion batteries (LiBs), sodium–sulfur
It details the physicochemical properties of nanoparticles—such as electronic, optical, and thermal characteristics—that enhance material performance. The paper particularly highlights the role of
Accordingly, a high-temperature, composite inorganic PCM (ZnO-NaNO3) with enhanced thermophysical properties was prepared, and its energy storage potential was investigated
Nano-phase change materials (Nano-PCMs) have emerged as a promising solution for improving the efficiency and thermal performance of thermal energy storage (TES) systems.
Recent research has focused on optimizing these nanomaterials for greater efficiency, sustainability, and cost-effectiveness, pushing the boundaries of what is possible in energy
ZnO-NaNO3 nanocomposite (2 wt% ZnO-NaNO3) with increased energy storage capacity and excellent cycling stability can be a potential TES material (composite PCM) for applications requiring
Simultaneous improvement of thermal conductivity and maintaining the energy storage density of PCM using additives is a real challenge. The present review discusses the effects of
A novel ternary eutectic salt, NaNO 3 -KNO 3 -Na 2 SO 4 (TMS), was designed and prepared for thermal energy storage (TES) to address the issues of the narrow temperature range
Hybrid PCM with nanoparticles has excellent potential to tailor thermo-physical properties and uplift the efficiency of energy storage systems. Synergistic use of PCM with nanomicromaterial can further
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