Progress in Polymer Composites for Different Applications

© 2022 by the authors; CC BY-NC-ND license

polyethylene; composite; fire behavior; fire retardant; copper slag; basalt powder; expanded vermiculite; flexible polyurethane foams; ground tire rubber; waste; filler modification; interfacial interactions; poly(lactic acid); polypropylene; flame retardancy; mechanical performance; sustainable fillers; injection molding; hot melt adhesive; carbon nanotubes; adhesion; rheology; microstructure; natural rubber; Gd₂O₃; self-healing; shielding; mechanical properties; X-rays; neutrons; polyurethane foams; PUR; vermiculite; rigid foams; thermal insulation; polyamide 11; basalt; flax; hybrid composites; low-velocity impact; temperature; polymer matrix composites; circular economy; polypropylene; post-printing waste; retained surgical items; polyvinyl chloride; bismuth oxychloride; barium sulfate; radiopacity; liquid chromatography coupled with triple quadrupole tandem mass spectrometry (LC-MS/MS); dental composites; bulk-fill composites; elution; residual monomer; polypropylene; PP; mineral-filled composites; calcium sulfate; gypsum; anhydrite II; melt mixing; thermal and mechanical properties; reactive extrusion; REx; heat deflection temperature (HDT); injection molding; automotive; engineering applications; cone calorimetry; deep eutectic solvents; fillers; fire behavior; microcrystalline cellulose; montmorillonite; thermoplastic starch; solar cell; functionalization; graphene; carbon nanotube; conducting polymer; composites; power conversion efficiency; supercapacitors; capacitance