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The effect of nano-sized filler particles on the crystalline-amorphous interphase and thermal properties in polyester nanocomposites
Journal Contribution - Journal Article
Poly(epsilon-caprolactone) (PCL) nanocomposites containing carbon nanotubes, layered silicates, sepiolite
or polyhedral oligomeric silsesquioxane (POSS) were characterized by advanced thermal analysis.
Adding carbon nanotubes or layered silicates increases the excess heat capacity in quasi-isothermal
crystallization experiments by MTDSC, pointing to an increased fraction of reversibly melting and
crystallizing material. In situ AFM during isothermal crystallization and SAXS during subsequent heating
reveal an altered PCL semi-crystalline morphology. The nucleating ability of the carbon nanotubes
induces a striking transcrystalline morphology, promoting the growth of secondary PCL crystals with an
increased fold surface energy and a reduced melting temperature. The altered crystalline-amorphous
interphase at the crystal fold surface houses the material that reversibly crystallizes and melts under
quasi-isothermal crystallization conditions. A fraction of this interphase is not able to crystallize but
converts into glassy, rigid amorphous material upon cooling prior to reaching the PCL main glass transition
temperature. Low aspect ratio sepiolite and POSS nanofillers barely nucleate the PCL crystallization
and therefore hardly affect the PCL semi-crystalline morphology and thermal behavior.
or polyhedral oligomeric silsesquioxane (POSS) were characterized by advanced thermal analysis.
Adding carbon nanotubes or layered silicates increases the excess heat capacity in quasi-isothermal
crystallization experiments by MTDSC, pointing to an increased fraction of reversibly melting and
crystallizing material. In situ AFM during isothermal crystallization and SAXS during subsequent heating
reveal an altered PCL semi-crystalline morphology. The nucleating ability of the carbon nanotubes
induces a striking transcrystalline morphology, promoting the growth of secondary PCL crystals with an
increased fold surface energy and a reduced melting temperature. The altered crystalline-amorphous
interphase at the crystal fold surface houses the material that reversibly crystallizes and melts under
quasi-isothermal crystallization conditions. A fraction of this interphase is not able to crystallize but
converts into glassy, rigid amorphous material upon cooling prior to reaching the PCL main glass transition
temperature. Low aspect ratio sepiolite and POSS nanofillers barely nucleate the PCL crystallization
and therefore hardly affect the PCL semi-crystalline morphology and thermal behavior.
Journal: Polymer
ISSN: 0032-3861
Volume: 53
Pages: 1494-1506
Publication year:2012
Keywords:Nanocomposites, Crystallization, Morphology