Synthesis of carbon-rich hybrid foam from GAP-modified polyurethane

Propellants, Explosives, Pyrotechnics

Volumn 33, Issue 5, 2008, Pages 373-380

  König, Alexander ^a   Kroke, Edwin ^b  

^a FRAUNHOFER INSTITUTE FOR CHEMICAL TECHNOLOGY ICT   (Germany)

^b TU BERGAKADEMIE FREIBERG   (Germany)

Author keywords

Foam; GAP; Glycidyl azide polymer; Polyurethane; Pyrolysis

Indexed keywords

ABS RESINS; AMMONIA; BIOLOGICAL MEMBRANES; CARBON; CARBON BLACK; CARBONIZATION; CHEMICAL REACTIONS; DECOMPOSITION; DEPOLYMERIZATION; FOURIER TRANSFORM INFRARED SPECTROSCOPY; GALLIUM ALLOYS; HYDROGEN; NITROGEN; NONMETALS; NUCLEAR MAGNETIC RESONANCE; OXYGEN; POLYMERS; PYROLYSIS; REACTION KINETICS; UREA;

ADIABATIC FLAME TEMPERATURES; AROMATIC STRUCTURES; AZIDO GROUPS; BUNSEN BURNERS; BURNING VELOCITIES; CARBONIZATION PROCESSES; CONDUCTIVITY MEASUREMENTS; DECOMPOSITION MECHANISMS; DECOMPOSITION PRODUCTS; DECOMPOSITION REACTIONS; DIPHENYL METHANES; ENERGETIC BINDERS; GAP; GLYCIDYL AZIDE POLYMER; GLYCIDYL AZIDE POLYMERS; HIGH TEMPERATURES; INERT ATMOSPHERES; MODIFYING AGENTS; OXYGEN CONTENTS; POLYMER BACKBONES; PU FOAMS; SOLID CARBONS; SPECIFIC SURFACES; SYNTHESIS OF; UREA GROUPS;

FOAMS;

EID: 55349122568     PISSN: 07213115     EISSN: 15214087     Source Type: Journal    
DOI: 10.1002/prep.200800014     Document Type: Article

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