Effects of carbon-based fillers on thermal properties of fatty acids and their eutectics as phase change materials used for thermal energy storage: A Review

Organic phase change materials (PCMs) are the most common heat storage components in latent heat based thermal energy storage (TES) systems. Among the different organic PCMs, fatty acids (FAs) have shown a real potential in important areas, such as, food and medical transportation, passive solar heating and cooling of buildings, etc., because of the suitable thermodynamic and kinetic properties. However, like all other organic PCMs, FAs also suffer from low thermal conductivity (TC) and sometimes seepage issues. Various conducting alien components (metal nanoparticles, metal oxides, etc.) and different carbon-based materials (expanded graphite, graphene, graphene oxide, carbon nanotubes, activated carbon, carbon nanofibers, and carbon black) have been evaluated extensively to enhance the TC. However, carbon-based materials were observed to be superior due to their excellent thermal conductivity, stability, lightweight, and lower cost. While analyzing the literature for this review article, it was found that the bulk of work focuses on FAs, and FAs based composite PCMs with carbon-based fillers and resulting PCMs demonstrated a good performance under the experimental conditions. No obvious discussion exists on the choice of carbon-based filler from a commercial point of view. So, this review attempts to critically evaluate the research work reported to date on the FAs and FA based composite PCMs, where carbon-based fillers have been used. This discussion is followed by comparative analysis to narrow the selection window for specific carbon filler in terms of the best performance.

Automated summary

Organic phase change materials play a crucial role in thermal energy storage, with fatty acids showing potential but facing issues such as low thermal conductivity and seepage. Combining carbon-based fillers with fatty acids can significantly enhance the performance.