Reprint

Bio and Synthetic Based Polymer Composite Materials

Edited by
October 2022
382 pages
  • ISBN978-3-0365-5240-8 (Hardback)
  • ISBN978-3-0365-5239-2 (PDF)

This is a Reprint of the Special Issue Bio and Synthetic Based Polymer Composite Materials that was published in

Chemistry & Materials Science
Engineering
Summary

For decades, synthetic fibers have been the leading commodity in the composites industry. However, synthetic fibers have many disadvantages, as they are non-biodegradable. Since synthetic fibers have many shortcomings, researchers have had growing interest in producing polymers that incorporate natural fibers. Natural fibers are becoming more common as a viable option due to the harmful environmental and health consequences of synthetic fibers. Concerns about the environment and the rising greenhouse effect, as well as increasing interest in the use of sustainable materials, has motivated researchers to investigate biocomposite materials. In today’s manufacturing environment, natural fiber composites are playing a prominent role in many vital applications, such as in wings of wind turbines, bicycle frames, automobile interiors, seat cushions, door panels. The great interest in natural fiber composites is due to their high performance, biodegradability, nonabrasive light weight, and low cost. Moreover, the widespread adoption of natural fibers and biopolymers as green materials is being motivated by the rapid depletion of petroleum supplies, as well as by a growing recognition of global environmental issues associated with the use of traditional plastics. The successful application of biopolymers and the promise of alternative pathways with a reduced carbon footprint arising from the use of green materials bodes well for the future design and development of ever more sophisticated green materials.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
kenaf composite; flammability; fire retardant; hybrid composite; tensile; morphology; pet yarn; epoxy; flame retardant; polymer composites; metal; metal components; characterization; combustion mechanism; biomedical; conducting polymers; corrosion; doped; electronics; shape memory polymers; sensors; actuators; optical limiting; biocomposites; kenaf; sugar palm; thermal; dynamic mechanical analysis; benzoylation; non-chemical pretreatment; lignocellulosic biomass; bioproducts; nanocellulose; membrane filter; microbes; surface functionalization; polycaprolactone; pine cone powder; graphite; dimensional stability; biodegradability; fracture energy; SEM; hybrid composite; glass fiber; basalt fiber; DMA; TMA; bacterial cellulose (BC); biopolymer; industrial waste; microbial cellulose; carbon source; nitrogen source; cornstarch; plasticizer; fructose; glycerol; film; properties; natural fiber; hybrid composite; cellulose; costing; processing; fiber-matrix adhesion; compression strength; foam; specific energy absorption; tube; natural and synthetic fibers; thermosetting polymers; L16 orthogonal array; Taguchi method; erosion mechanism; SEM analysis; prosthetic applications; wheat biocomposite; wheat starch; wheat gluten; wheat fiber; antioxidant; antimicrobial; 3D printing; bio-inspired structure; energy absorption; fused deposition modelling; honeycomb structure; n/a

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