posted on 2024-09-27, 07:46authored byCicely
M. Warne, Jeppe Madsen, Georg M. Guebitz, Bryan Dalton, Reeta Davis, Tanja Narancic, Kevin O’Connor, Anders E. Daugaard, Alessandro Pellis
Poly-3-hydroxybutyrate (PHB) is a promising biopolymer
that has
the potential to replace fossil-based plastics yet is currently limited
by its poor mechanical properties. A library of oligomeric polyesters
containing adipates, furanoates, phathalates, and pyridinecarboxylates
were enzymatically synthesized and evaluated as PHB additives. Across
the series of additives, the pyradinecarboxylate oligoesters served
as the most efficient plasticizers, whereas the phthalate was found
to influence the rate of crystallization to the greatest extent. Due
to the differences in additive miscibility, plasticization, and extent
of crystallization, the compounds showed significantly different mechanical
properties. Several additives promoted efficient crystallization at
high cooling rates, such as phthalate oligomer P5, which resulted
in a material that crystallized four times faster than pure PHB, and
produced a material with smaller spherulites. This difference in morphology
was to some extent reflected in the mechanical properties, as addition
of PHB–P5 resulted in a 42% decrease in the Young’s
modulus. Overall, the combined effects of the degree and rate of crystallization,
as well as the nature of the amorphous phase, prevented obvious trends
from emerging.