Reprint
Advances in Bio-Based and Biodegradable Polymeric Composites
Edited by
January 2023
552 pages
- ISBN978-3-0365-6492-0 (Hardback)
- ISBN978-3-0365-6491-3 (PDF)
This is a Reprint of the Special Issue Advances in Bio-Based and Biodegradable Polymeric Composites that was published in
Chemistry & Materials Science
Engineering
Summary
This reprint summarizes recent advances in the production and research of biobased and biodegradable polymeric composites for various applications. The development and characterization of environmentally friendly, conductive and biomedical materials as well as materials with barrier and antimicrobial properties have been considered and discussed.
Format
- Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
DMAP-lignin epoxide; bio-based epoxy resin; composite resin; tensile strength; chitosan; fish scales; Prochilodus magdalenae; antibacterial agent; natural fiber; rice husk; biocomposites; physicomechanical; thermal behavior; antibacterial; bionanocomposite; pectin; zinc oxide; crosslinking; cell matrices; Fs bioscaffolds structuring; ultra-short functionalization of cell matrices; tissue engineering; temporal scaffolds; PLA texturing; aminated graphene; graphene modification; grafting from; oligomers of glutamic acid; poly-ε-caprolactone; biocompatible polymer composites; humidity sensor; polyaniline; biopolymer; hydration; adsorption; electrical conductivity; response/recovery time; hysteresis; sensing mechanism; hydrophilicity/hydrophobicity; poly(lactic acid); Chinese spirits distiller’s grains; barrier; mechanical behavior; hydrophobicity; biodegradable properties; bacterial cellulose; ionic liquids; 3D-printing; mechanical properties; ion gels; antibacterial activity; biocompatible; chitosan; composite hydrogel; drug release; drug delivery; PEDOT: PSS; conducting polymer; conductive scaffolds; degradation rate; biocompatibility; fabrication of scaffolds; biomedical application; tissue engineering; extractions; cellulose; crosslink mechanism; biodegradable; waste materials; natural filler; latex; composite; mechanical properties; surface modifications; biodegradable polymer; electrospinning; fungicide; Phaeomoniella chlamydospora; Phaeoacremonium aleophilum; esca; polylactic acid; turmeric essential oil; chitosan; TGA; FT-IR; antimicrobial and antioxidant properties; S. aureus; E. coli; antimicrobial packaging; biodegradable; natural fibre; polymer composite; sustainable; poly(lactic acid); MWNT-Ag; GO; dispersion; electrical conductivity; biodegradable polymer; biocomposite; water diffusion; modeling; environmental ageing; durability; mechanical properties; thermomechanical properties; adhesion parameter; biocomposites; polybutylene succinate; polymer films; fiber; cellulose; bio-reinforcement; microcrystalline cellulose; nanocrystalline cellulose; cellulose fibers; cellulose modification; aliphatic polyesters; polyhydroxyalkanoates; poly(lactic acid); poly(ε-caprolactone); poly(glycolic acid); poly(lactic acid-co-glycolic acid); poly(hydroxybutyrate); poly(butylene succinate); (bio)composites; “green” materials; mechanical properties; thermal properties; degradation; biocompatibility; biocomposites; polyaniline colloids; starch; steric stabilizer; cyclic voltammetry; DFT; AIM study; COSMO-RS; biodegradable film; corn starch; chitosan; cellulose nanocrystals; antimicrobial film; nanocomposite; thermoplastic starch; nanocellulose; bentonite; biocomposite; aging; retrogradation; tuna skin by-product; fresh-cut watermelon; extract tea; edible coating; 3D-printing; PLA polymer; biological filler; mechanical; dynamic-mechanical; thermal; decomposition; wettability; surface appearance; n/a; poly(lactic acid); block copolymer; cassava starch; biocomposites; thermal stability; green composites; poly(lactic acid); poly(hydroxybutyrate); cellulose; micronized fibers; epoxidized linseed oil; sugar-based surfactant; mechanical properties; thermal properties; biodegradability