Abstract
The understanding of microbial growth dynamics during in situ fermentation and production of bacterial cellulose (BC) with impressive properties mimicking artificial nacre, suitable for commodity applications remains fundamentally challenging. Fabrication of BC/graphene films through a single step in situ fermentation with improved properties provides a sustainable replacement to the conventional chemical-based modification using toxic compounds. This work reports the effect of reduced graphene oxide (RGO) on in situ fermentation kinetics and demonstrates the formation of percolated-network in BC/RGO nanostructures. The evaluation of kinetic parameters shows that the specific growth rate reaches optimal values at 3 wt % RGO loadings, with mixed growth associated BC production behavior. The two-dimensional graphene sheets uniformly dispersed into a three-dimensional matrix of BC nanofibers via hydrogen-bonded interactions along with in situ reductions of RGO sheets, as confirmed from spectroscopic studies. This study also demonstrates the presence of percolated network-like structures between BC fibers and RGO platelets, which resulted in the formation of nanostructures with exceptional mechanical robustness and electrical conductivity. The physicochemical and structural properties of fabricated BC/RGO films were found to significantly depend upon the RGO compositions as well as fermentation conditions. We envision that the proposed ecofriendly and scalable technology for the formation of BC/RGO films with excellent inherent properties and performance will attract great interest for its prospective applications in flexible electronics.
Highlights
Bacterial cellulose (BC) is a microbially derived biopolymer which has recently attracted great attention from both academia as well as industrial researchers
A BC/reduced graphene oxide (RGO) nanocomposite fabrication route based on an in situ fermentation approach with homogeneous dispersion and percolated-network formation was demonstrated in this study
It was observed that the physicochemical properties of produced BC/RGO nanocomposites were subjected to the fermentation condition and kinetics that provide a unique platform in tailoring the nanostructure properties depending on targeted applications
Summary
Bacterial cellulose (BC) is a microbially derived biopolymer which has recently attracted great attention from both academia as well as industrial researchers. BCs offers unique physicochemical or structural properties and have potential application in numerous fields. BC is a linear polysaccharide of glucan chains (C6H10O5)n, which consists of fibrils of nanodimensions (
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