1 research outputs found
Role of the Branched PEG‑<i>b</i>‑PLLA Block Chain in Stereocomplex Crystallization and Crystallization Kinetics for PDLA/MPEG‑<i>b</i>‑PLLA‑<i>g</i>‑glucose Blends with Different Architectures
The
isothermal crystallization behavior and corresponding morphology
evolution of poly(d-lactic acid) (PDLA) blends with PLLA6.7k or MPEG-b-PLLA6.7k-g-glucose with different architectures and different PLLA-grafted
copolymer contents were investigated. The formation of stereocomplexes
(SCs) in between the chain branched structure of MPEG-b-PLLA6.7k-g-glucose and PDLA chains acting
as the physical crosslinking points slows down the motion of PDLA
chains, but the SCs could act as a heterogeneous nucleating agent
for the late formation of homocrystals (HCs) in the blend system,
accelerating the crystallization kinetics of HCs through enhancing
the nucleation density. For PDLA/MPEG-b-PLLA6.7k-g-glucose blends, the mobility of SCs
in the blend system and the nucleation density of SCs in the blends
exhibit oppositional behavior during the isothermal crystallization
at a Tc of 130 °C. The evolution
of the crystal growth and structure during the isothermal crystallization
process by rheometry has revealed the interesting role of the branched
chains of MPEG-b-PLLA6.7k-g-glucose in the mechanism of the crystallization in PDLA blends