Electrically Conductive Biocomposites Based on Poly(3-hydroxybutyrate-co-3-hydroxyvalerate) and Wood-Derived Carbon Fillers

In this paper, biobased carbons were used as fillers in poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV). The mechanical and electrical properties of these 100% biocomposites were analyzed. First, biocarbons were prepared from wood dust and cellulose fibers using carbonization temperatures rangin...

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Published in:Journal of composites science 2022-08, Vol.6 (8), p.228
Main Authors: Unterweger, Christoph, Ranzinger, Matija, Duchoslav, Jiri, Piana, Francesco, Pasti, Igor, Zeppetzauer, Franz, Breitenbach, Stefan, Stifter, David, Fürst, Christian
Format: Article
Language:English
Subjects:
biocarbon
biocomposites
Biomedical materials
Carbon black
Carbon content
Carbon fibers
Carbonization
Cellulose fibers
Dust
electrical conductivity
Electrical properties
Electrical resistivity
Fillers
Graphene
Graphitic structure
Injection molding
Lignin
Mechanical properties
Percolation
PHBV
Polymer matrix composites
Polymers
Software
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Summary:In this paper, biobased carbons were used as fillers in poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV). The mechanical and electrical properties of these 100% biocomposites were analyzed. First, biocarbons were prepared from wood dust and cellulose fibers using carbonization temperatures ranging 900–2300 °C. XRD revealed significant improvements of the graphitic structure with increasing temperatures for both precursors, with slightly higher ordering in wood-dust-based carbons. An increase of the carbon content with continuous removal of other elements was observed with increasing temperature. The carbonized cellulose fiber showed an accumulation of Na and O on the fiber surface at a carbonization temperature of 1500 °C. Significant degradation of PHBV was observed when mixed with this specific filler, which can, most probably, be attributed to this exceptional surface chemistry. With any other fillers, the preparation of injection-molded PHBV composites was possible without any difficulties. Small improvements in the mechanical performance were observed, with carbonized fibers being slightly superior to the wood dust analogues. Improvements at higher filler content were observed. These effects were even more pronounced in the electrical conductivity. In the range of 15–20 vol.% carbonized fibers, the percolation threshold could be reached, resulting in an electrical conductivity of 0.7 S/cm. For comparison, polypropylene composites were prepared using cellulose fibers carbonized at 2000 °C. Due to longer fibers retained in the composites, percolation could be reached in the range of 5–10 vol.%. The electrical conductivity was even higher compared to that of composites using commercial carbon fibers, showing a great potential for carbonized cellulose fibers in electrical applications.
ISSN:2504-477X
2504-477X
DOI:10.3390/jcs6080228