Reprint

Mechanical Performance of Sustainable Bio-Based Compounds

Edited by
February 2023
572 pages
  • ISBN978-3-0365-6685-6 (Hardback)
  • ISBN978-3-0365-6684-9 (PDF)

This is a Reprint of the Special Issue Mechanical Performance of Sustainable Bio-Based Compounds that was published in

Chemistry & Materials Science
Engineering
Summary

This Special Issue collected original contributions, both research papers and reviews, showing recent results and/or positive advances in the behavior of new sustainable bio-materials under applied mechanical stress, both in static and dynamic mode, and evaluating the characteristics of resistance, moduli and/or viscoelasticity, in view of potential applications, such as tissue engineering, medical devices, surgical or dental implants, manufacturing of human parts, agriculture, packaging, textiles, electronics, automotive and aerospace, green buildings, and architecture and construction.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
biodegradable polymers; mechanical properties; rheology; processing; moisture content; characterisation; particleboard; natural fiber composites; Rhizophora spp.; mechanical properties; biodegradable; thermomechanical properties; thermal properties; dicumyl peroxide; Joncryl; wood-polymer composites (WPC); recycled thermoplastics; torque measurements; rheological properties; dynamic mechanical analyses; hot-pressing; paper web; fibre; lignin; diffusion; activation energy; wood flour; wood pellets; wood–plastic composites; transportation costs; physical properties; mechanical properties; interfacial bond strength; wood-polymer composites; wood-polymer interface; XPS; PLA/starch; compatibilizer; vegetable oil-based additive; masterbatch; epoxidized natural rubber; halloysite nanotubes; urea; tensile properties; wide-angle X-ray scattering; jute fabrics; 3D printing; mechanical properties; eco-friendly composites; gellan gum; virgin coconut oil; hydrogels; biomaterials; wound dressing; polylactic acid; chitosan; organosolv lignin; modifying agent; biocomposites; biodegradable polymers; nanocomposites; durability; biodegradation; environmental ageing; creep; modelling; crazing; biodegradation; polyaniline; polylactic acid; fruit waste; vegetable waste; waste valorization; bioactive compound; active packaging; biocomposites; by-product; extraction; thermal processing; non-thermal processing; mechanical properties; sugar palm fiber; poly(lactic acid); alkaline treatment; benzoyl chloride treatment; hybrid composites; biodegradable thermoplastic; coating; Amdry 6420; Metco 143; Metco 136F; hardness; adhesion; structure; Pandanus amaryllifolius fibre; natural fibres; composite; biodegradable plastics; polyhydroxybutyrate; polymer composites; compounding; injection molding; composite; MOR; MOE; IB; panel; nanocomposite; acrylic denture teeth; nano ZrO2 particles; wear behavior; microstructure; microhardness; polymerization; polymethyl methacrylate resin; textiles; sustainability; biopolymers; carboxymethyl cellulose; drying effects; wound dressing; coating layers; fiber-based material; mechanical properties; hydrothermal-mechanical pretreatment; agricultural wastes; energy efficiency; waste generation; single fiber test; tensile properties; Weibull distribution; gauge length; environmental degradation; UV aging; moisture; durability; tissue engineered vascular grafts; biomaterials; biodegradable; biomechanical stimulation; mechanical properties; rice bran; ultrasound cavitation; resistant starch microstructure; crystallinity; hydration properties; mechanical performance; mechanical properties; physical treatment; chemical treatment; biological treatment; κ-carrageenan–gelatin hydrogel; supramolecular structure; mechanical performance; n/a