Synthesis of poly-(R)-3 hydroxyoctanoate (PHO) and its graphene nanocomposites

Ahmed Abdala; John Barrett; Friedrich Srienc

doi:10.1021/bk-2013-1144.ch014

Synthesis of poly-(R)-3 hydroxyoctanoate (PHO) and its graphene nanocomposites

Ahmed Abdala, John Barrett, Friedrich Srienc

Biotechnology Institute

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

2 Scopus citations

Abstract

Polyhydroxyalkanoates are a popular class of bioplastics valued for their rapid biodegradadion, biocompatibility, and renewable feedstocks. While there are already a few commercial applications for these biopolymers, a greater diversity of properties is needed to compete with petroleum based polymers. In this chapter, we report the synthesis and characterization of polyhdroxyoctanoate and its nanocomposite with thermally reduced graphene. The results indicate the incorporation of graphene into the PHO matrix leads to a small upshift in the glass transition, enhance the thermal stability, and ∼600% increase in modulus. Electrical percolation between 0.5 and 1 vol.% TRG was obtained.

Original language	English (US)
Title of host publication	Green Polymer Chem
Subtitle of host publication	Biocatalysis and Materials II
Publisher	American Chemical Society
Pages	199-209
Number of pages	11
ISBN (Print)	9780841228955
DOIs	https://doi.org/10.1021/bk-2013-1144.ch014
State	Published - Nov 22 2013

Publication series

Name	ACS Symposium Series
Volume	1144
ISSN (Print)	0097-6156
ISSN (Electronic)	1947-5918

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title = "Synthesis of poly-(R)-3 hydroxyoctanoate (PHO) and its graphene nanocomposites",

abstract = "Polyhydroxyalkanoates are a popular class of bioplastics valued for their rapid biodegradadion, biocompatibility, and renewable feedstocks. While there are already a few commercial applications for these biopolymers, a greater diversity of properties is needed to compete with petroleum based polymers. In this chapter, we report the synthesis and characterization of polyhdroxyoctanoate and its nanocomposite with thermally reduced graphene. The results indicate the incorporation of graphene into the PHO matrix leads to a small upshift in the glass transition, enhance the thermal stability, and ∼600% increase in modulus. Electrical percolation between 0.5 and 1 vol.% TRG was obtained.",

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AU - Srienc, Friedrich

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N2 - Polyhydroxyalkanoates are a popular class of bioplastics valued for their rapid biodegradadion, biocompatibility, and renewable feedstocks. While there are already a few commercial applications for these biopolymers, a greater diversity of properties is needed to compete with petroleum based polymers. In this chapter, we report the synthesis and characterization of polyhdroxyoctanoate and its nanocomposite with thermally reduced graphene. The results indicate the incorporation of graphene into the PHO matrix leads to a small upshift in the glass transition, enhance the thermal stability, and ∼600% increase in modulus. Electrical percolation between 0.5 and 1 vol.% TRG was obtained.

AB - Polyhydroxyalkanoates are a popular class of bioplastics valued for their rapid biodegradadion, biocompatibility, and renewable feedstocks. While there are already a few commercial applications for these biopolymers, a greater diversity of properties is needed to compete with petroleum based polymers. In this chapter, we report the synthesis and characterization of polyhdroxyoctanoate and its nanocomposite with thermally reduced graphene. The results indicate the incorporation of graphene into the PHO matrix leads to a small upshift in the glass transition, enhance the thermal stability, and ∼600% increase in modulus. Electrical percolation between 0.5 and 1 vol.% TRG was obtained.

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ER -

Synthesis of poly-(R)-3 hydroxyoctanoate (PHO) and its graphene nanocomposites

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