Advances in erythritol-based composite phase change materials

Phase change materials (PCMs) can realize energy absorption, storage, and release by the phase change latent heat, which is beneficial for heat energy management. Recently, erythritol, with a phase transition temperature of about 118 °C and latent heat of about 314 J g −1 , has been extensively appl...

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Published inSustainable energy & fuels Vol. 8; no. 7; pp. 1389 - 144
Main Authors Peng, Fuyan, Zhu, Xuhai, Lin, Rongjun, Lu, Rui, Lu, Fang
Format Journal Article
LanguageEnglish
Published London Royal Society of Chemistry 26.03.2024
Subjects
Composite materials
Energy absorption
Energy management
Energy storage
Erythritol
Garbage collection
Heat
Heat conductivity
Heat recovery
Heat transfer
Latent heat
Phase change materials
Phase transitions
Supercooling
Thermal conductivity
Thermal insulation
Thermal management
Transition temperature
Transition temperatures
Waste heat recovery
Waste recovery
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Summary:Phase change materials (PCMs) can realize energy absorption, storage, and release by the phase change latent heat, which is beneficial for heat energy management. Recently, erythritol, with a phase transition temperature of about 118 °C and latent heat of about 314 J g −1 , has been extensively applied as a phase change material in the field of medium temperature energy storage, relying on its high energy storage density, non-corrosiveness, etc. However, the severe supercooling and relatively low thermal conductivity of erythritol during phase transition significantly prevent widespread applications. This review summarizes the latest developments, emerging trends, and challenges of erythritol for advanced PCMs. We proceed from the importance of the structure-property relationship of erythritol in the performance improvement of PCMs. Then, the fundamentals related to the advantages and disadvantages of erythritol as a phase change material are systematically discussed. Further, several methods to inhibit the supercooling performance and improve the thermal conductivity of erythritol are summarized for deepening future studies and extending the applications of erythritol for high-performance PCMs. Finally, the major preparation strategies and applications of erythritol-based PCMs are emphasized in the thermal management of solar heat collection, waste heat recovery, and antibacterial and thermal insulation. Erythritol-based composite phase change materials (PCMs) can realize energy absorption, storage, and release by the phase change latent heat, which is beneficial for heat energy management.
ISSN:2398-4902
2398-4902
DOI:10.1039/d4se00171k