2021
DOI: 10.3390/polym13162663
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Incorporation of Biochar to Improve Mechanical, Thermal and Electrical Properties of Polymer Composites

Abstract: The strive for utilization of green fillers in polymer composite has increased focus on application of natural biomass-based fillers. Biochar has garnered a lot of attention as a filler material and has the potential to replace conventionally used inorganic mineral fillers. Biochar is a carbon rich product obtained from thermochemical conversion of biomass in nitrogen environment. In this review, current studies dealing with incorporation of biochar in polymer matrices as a reinforcement and conductive filler … Show more

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Cited by 82 publications
(55 citation statements)
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“…Moreover, the addition of increasing amounts of a stiff filler accounted for an overall stiffening of the composites. The reinforcing effect of biochar on Young’s modulus of polymer-based composites is widely reported in the literature [ 14 , 60 ]. Moreover, the greater the amount of added HFB, the lower the elongation ability ( Figure 7 B) of the material because of the poor interface interaction between polymer and filler.…”
Section: Resultsmentioning
confidence: 99%
“…Moreover, the addition of increasing amounts of a stiff filler accounted for an overall stiffening of the composites. The reinforcing effect of biochar on Young’s modulus of polymer-based composites is widely reported in the literature [ 14 , 60 ]. Moreover, the greater the amount of added HFB, the lower the elongation ability ( Figure 7 B) of the material because of the poor interface interaction between polymer and filler.…”
Section: Resultsmentioning
confidence: 99%
“…To overcome these drawbacks, a biochar/polymer composite can be fabricated for undemanding separation. This is a win-win strategy, as the biochar can enhance the mechanical, thermal, and electrical properties of the polymer [131,132], and the polymer film will ease the reusability and catalyst stability. Amongst polymers, organics decontamination using floating (low-density) polymer-based materials (e.g., linear low-density polyethylene (LLDPE)) is highly desirable as no stirring is required, separation of catalyst is facile, and the floating of the catalyst allows excellent utilization of light irradiation (in the case of photocatalysis).…”
Section: Stability and Reusabilitymentioning
confidence: 99%
“…The sharp increase in problems associated with global warming, environmental pollution, and depleting fossil fuel resources has created the need for the development of material systems and fabrication processes that are sustainable. Plant- and animal-based materials are being rapidly explored as alternative materials for various applications. Reinforcing polymer matrices with inexpensive sustainable carbon filler materials has been explored rigorously in the past by researchers particularly to mitigate dependency on fossil fuel-based reinforcing fillers like carbon nanotubes and graphene nanoplatelets. The reinforcing ability of biochar carbon mainly depends on the inherent strength of the fillers and mechanical interlocking between the filler and host polymer matrix. For this reason, biochar with microsize pores is preferred to create effective interlocking. , However, such biochars with micropores due to their relatively poor mechanical, thermal, and electrical properties are loaded in huge weight percentages (15–30%) to create a composite with improved properties.…”
Section: Introductionmentioning
confidence: 99%