Heterogeneous Bubble Nucleation by Homogeneous Crystal Nuclei in Poly(l‐Lactic Acid) Foaming

Abstract: A novel method to enhance and control bubble nucleation in poly(l-lactic acid) (PLLA) foaming, not relying on external nucleating agents, is presented. Amorphous PLLA is annealed at temperatures close to its glass transition, to allow local alignment of polymer chains in the form of nanosized aggregates, called homogeneous crystal nuclei (HCN). PLLA containing HCN is then foamed after sorption of CO 2 at 120 °C and 10 MPa. Under the chosen experimental conditions, HCN can promote growth of PLLA spherulites tha… Show more

“…Moreover, when selecting the foaming temperature, it must be considered that a polymer's glass transition and crystallization temperatures decrease due to the plasticizing effect of CO 2 [76,77]. The presence of crystals during foaming also affects the final foam structure, as crystal formation not only boosts bubble nucleation but also decreases the CO 2 amount dissolved in the polymer because CO 2 can be dissolved only in the amorphous regions [78]. The CO 2 content also plays an important role in foam expansion, since a low CO 2 content does not lead to significant foam expansion, while larger CO 2 contents show intense shrinkage upon ageing.…”

“…Other strategies than the addition of external nucleation agents could be used to boost cell nucleation. Long et al [78] explored the viability of homogeneous crystal nuclei to improve and control cell nucleation and growth in PLLA foams without the addition of external nucleating agents. Amorphous PLLA was annealed at temperatures close to its glass transition temperature to favour the local alignment of polymer chains into nanosized aggregates, which they called homogeneous crystal nuclei.…”

Forefront Research of Foaming Strategies on Biodegradable Polymers and Their Composites by Thermal or Melt-Based Processing Technologies: Advances and Perspectives

“…Moreover, when selecting the foaming temperature, it must be considered that a polymer's glass transition and crystallization temperatures decrease due to the plasticizing effect of CO 2 [76,77]. The presence of crystals during foaming also affects the final foam structure, as crystal formation not only boosts bubble nucleation but also decreases the CO 2 amount dissolved in the polymer because CO 2 can be dissolved only in the amorphous regions [78]. The CO 2 content also plays an important role in foam expansion, since a low CO 2 content does not lead to significant foam expansion, while larger CO 2 contents show intense shrinkage upon ageing.…”

“…Other strategies than the addition of external nucleation agents could be used to boost cell nucleation. Long et al [78] explored the viability of homogeneous crystal nuclei to improve and control cell nucleation and growth in PLLA foams without the addition of external nucleating agents. Amorphous PLLA was annealed at temperatures close to its glass transition temperature to favour the local alignment of polymer chains into nanosized aggregates, which they called homogeneous crystal nuclei.…”

Forefront Research of Foaming Strategies on Biodegradable Polymers and Their Composites by Thermal or Melt-Based Processing Technologies: Advances and Perspectives

CO2-diffusion controlled mesophase formation in poly(l-lactic acid) and its effect on cold-crystallization

Controllable cell structures of poly(ether-block-amide) foams via isothermal melt crystallization-foaming in supercritical CO2