A comparative study of the effect of multidimensional carbon fillers on polystyrene using supercritical carbon dioxide foaming

Abstract

Due to its low thermal conductivity on average (~0.039 W/(m·K)), supercritical expanded polystyrene (PS) foam could be used as an insulation material in buildings to save energy and minimize the maintenance costs. However, the specific solubilizing and fast diffusing behavior of CO 2 in PS limited the formation of micropores and the further increase of macropores, which resulted in on limited decrease in thermal conductivity. In this study, one-dimensional carbon nanotubes, two-dimensional graphene, and three-dimensional activated carbon were loaded on PS using supercritical CO 2 foaming. The results demonstrated that all these three carbon nanomaterials doped on PS could generate more micropores and macropores during foaming. Moreover, the composite PS foams presented much lower specific thermal conductivity (0.360 cm 3 ·W/(g·m·K)), higher cell density (up to 3.23 × 10 14 cell/cm 3 ), and compressive modulus (up to 1.66 MPa), overwhelming those of pure PS. Particularly, the continuous infrared thermography measurements found that two-dimensional graphene thermally outperformed the others, meaning comparatively better heat insulation effect after foaming. Therefore, multidimensional carbon nanomaterials were promising to minimize the negative environmental impact of PS foaming while comprehensively reinforcing it. • The reinforcements of multidimensional carbon fillers on polystyrene were varied. • Graphene thermally/physically outperformed carbon nanotubes and activated carbon. • Improved coupling of its plasmon with phonon-polariton thermally enhanced graphene. • Carbon nanomaterials are comprehensively better fillers for polystyrene.