Abstract
In recent years, multifunctional form-stable composite phase change materials have been the research focus in the field of thermal energy storage. In this work, magnetic wood-based composite phase change materials are prepared via the impregnation of a compound of 1-tetradecanol and Fe3O4 nanoparticles into delignified balsa wood. Delignified balsa wood, which has porous structure with low density and high loading content of over 80%, was used as a supporting material. The addition of Fe3O4 nanoparticles provides an excellent magnetic property and improves the solar-to-thermal conversion efficiency of the composite. Benefiting from the magnetothermal effect, the magnetic wood-based composite phase change materials can be heated under an alternating magnetic field. Also, the magnetic wood-based composite phase change materials exhibit large latent heat (179 J/g), excellent thermal reliability after 100 heating-cooling cycles, and outstanding shape stability. And they have good thermal stability below 112 ℃. Considering the easy processing and excellent property, the magnetic wood-based composite phase change materials have great prospect in multifunctional thermal energy storage in practical applications.
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