Fire retardancy in 2008 Composites and Nanocomposites / 1: |
Thermal evolution of Nanocomposites and Fire Testing Performance / 2: |
Functionalized-carbon multiwall nanotube as flame retardant for polylactic acid / 3: |
Use of Layered Double Hydroxides as Polymer Fire Retardant Additives: Advantages and Challenges / 4: |
Effect of Flame Retardants on the Thermal, Burning and Char Formation Behaviour of Polypropylene / 5: |
Flammability of Polymer/Inorganic Nanocomposites / 6: |
Flame retardant PET/PC blends compatibilized by organomodified Montmorillonites / 7: |
Development of Polyurea Nanocomposites with Improved Fire Retardancy / 8: |
Fire Retardant Mechanism of Acrylonitrile Copolymers Containing Nanoclay / 9: |
Fire and Engineering Properties of Polyimide-Aerogel Hybrid Foam Composites for Advanced Applications / 10: |
Advanced Flame-retardant Epoxy Resins for Composite Materials Conventional Fire Retardants / 11: |
Fire Retardancy of Polypropylene Composites using Intumescent Coatings / 12: |
Combustion and thermal properties of polylactide with an effective phosphate-containing flame retardant oligomer / 13: |
Effects of boric acid on flame retardancy of IFR polypropylene system containing a caged bicyclic phosphate / 14: |
Brominated aryl phospholane flame retardants / 15: |
Development of multifuntional flame retardants for polymeric systems / 16: |
Flammability of Fluoropolymers / 17: |
Up-Cycling of Rubber-Plastic Waste to Fire Retarded System Metal-Containing Systems / 18: |
A Review of Transition Metal-Based Flame Retardants Transition Metal Oxide/Salts, and Complexes / 19: |
Salen Copper Complexes: A Novel Flame Retardant for Thermoplastic Polyurethane Toxicity / 20: |
Effects of Fire Retardants and Nanofillers on the Fire Toxicity Thermal Degradation Studies / 21: |
Modelling Thermal Degradation of Flame-retarded Epoxy Resin Formulations under Different Heating Conditions / 22: |
Effect of Ambient Oxygen Concentration on Thermal Decomposition of Polyurethanes Based on MDI and PMDI / 23: |
Fire retardancy in 2008 Composites and Nanocomposites / 1: |
Thermal evolution of Nanocomposites and Fire Testing Performance / 2: |
Functionalized-carbon multiwall nanotube as flame retardant for polylactic acid / 3: |
Use of Layered Double Hydroxides as Polymer Fire Retardant Additives: Advantages and Challenges / 4: |
Effect of Flame Retardants on the Thermal, Burning and Char Formation Behaviour of Polypropylene / 5: |
Flammability of Polymer/Inorganic Nanocomposites / 6: |