Advanced Flame Retardant Materials

Recent disasters caused by the spread of fire in buildings and in transportations remind us of the importance of fire protection. Using flame-retardant materials is one important element of the firefighting strategy, which aims to prevent fire development and propagation. These materials are used in...

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Autor principal: Laoutid, Fouad
Formato: Online
Lenguaje:inglés
Publicado: MDPI - Multidisciplinary Digital Publishing Institute 2021
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Acceso en línea:44788
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author Laoutid, Fouad
author_browse Laoutid, Fouad
author_facet Laoutid, Fouad
author_sort Laoutid, Fouad
collection Directory of Open Access Books
description Recent disasters caused by the spread of fire in buildings and in transportations remind us of the importance of fire protection. Using flame-retardant materials is one important element of the firefighting strategy, which aims to prevent fire development and propagation. These materials are used in different applications, such as in textiles, coatings, foams, furniture, and cables. The development of more efficient and environmentally friendly flame-retardant additives is an active multidisciplinary approach that has attracted a great deal of interest. Studies have aimed at the development of new, sustainable, and flame-retardant additives/materials, providing high performance and low toxicity. Also studied were their properties during ageing and recycling, as well as modeling physical and chemical processes occuring before ignition and during their combustion. The development of sustainable flame retardants and understanding their modes of action provide a strong link between these topics and cover many fields from organic chemistry, materials engineering, and toxicology, to physics and mathematics.
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publisherStr MDPI - Multidisciplinary Digital Publishing Institute
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spelling doab-20.500.12854ir-401932023-12-20T18:40:30Z Advanced Flame Retardant Materials Laoutid, Fouad Q1-390 QC1-999 nano-SiO2 polymer flammability biodegradable fracture toughness microcalorimetry of combustion lignin ZIF-8@GO hybrids poly(3-hydroxybutyrate) (PHB) biomaterials epoxy novolac resin phosphorylation PLA ROP thermal decomposition polyamide 11 flame retardant biobased materials flame retardance flexible phenolic resin condensed phase aluminum diethylphosphinate PLA melamine triazine chain extension EVA/LLDPE blend reactive flame retardancy dielectric constant clay composites ammonium polyphosphate phosphorus-containing flame retardant flame retardancy calorimetry pyrolysis–combustion flow calorimetry fire reaction DOPO van Krevelen approach melamine wire and cable cotton fabrics organophosphorus compounds flame-retardant lignin nanoparticles polylactide group contributions bic Book Industry Communication::G Reference, information & interdisciplinary subjects::GP Research & information: general Recent disasters caused by the spread of fire in buildings and in transportations remind us of the importance of fire protection. Using flame-retardant materials is one important element of the firefighting strategy, which aims to prevent fire development and propagation. These materials are used in different applications, such as in textiles, coatings, foams, furniture, and cables. The development of more efficient and environmentally friendly flame-retardant additives is an active multidisciplinary approach that has attracted a great deal of interest. Studies have aimed at the development of new, sustainable, and flame-retardant additives/materials, providing high performance and low toxicity. Also studied were their properties during ageing and recycling, as well as modeling physical and chemical processes occuring before ignition and during their combustion. The development of sustainable flame retardants and understanding their modes of action provide a strong link between these topics and cover many fields from organic chemistry, materials engineering, and toxicology, to physics and mathematics. 2021-02-11T07:45:39Z 2021-02-11T07:45:39Z 2020-04-07 23:07:09 2020 book 44788 9783039283514 9783039283507 https://directory.doabooks.org/handle/20.500.12854/40193 eng application/octet-stream Attribution-NonCommercial-NoDerivatives 4.0 International https://mdpi.com/books/pdfview/book/2065 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-03928-351-4 10.3390/books978-3-03928-351-4 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783039283514 9783039283507 190 open access
spellingShingle Q1-390
QC1-999
nano-SiO2
polymer flammability
biodegradable
fracture toughness
microcalorimetry of combustion
lignin
ZIF-8@GO hybrids
poly(3-hydroxybutyrate) (PHB)
biomaterials
epoxy novolac resin
phosphorylation
PLA ROP
thermal decomposition
polyamide 11
flame retardant
biobased materials
flame retardance
flexible
phenolic resin
condensed phase
aluminum diethylphosphinate
PLA
melamine triazine
chain extension
EVA/LLDPE blend
reactive flame retardancy
dielectric constant
clay
composites
ammonium polyphosphate
phosphorus-containing flame retardant
flame retardancy
calorimetry
pyrolysis–combustion flow calorimetry
fire reaction
DOPO
van Krevelen approach
melamine
wire and cable
cotton fabrics
organophosphorus compounds
flame-retardant
lignin nanoparticles
polylactide
group contributions
bic Book Industry Communication::G Reference, information & interdisciplinary subjects::GP Research & information: general
Laoutid, Fouad
Advanced Flame Retardant Materials
title Advanced Flame Retardant Materials
title_full Advanced Flame Retardant Materials
title_fullStr Advanced Flame Retardant Materials
title_full_unstemmed Advanced Flame Retardant Materials
title_short Advanced Flame Retardant Materials
title_sort advanced flame retardant materials
topic Q1-390
QC1-999
nano-SiO2
polymer flammability
biodegradable
fracture toughness
microcalorimetry of combustion
lignin
ZIF-8@GO hybrids
poly(3-hydroxybutyrate) (PHB)
biomaterials
epoxy novolac resin
phosphorylation
PLA ROP
thermal decomposition
polyamide 11
flame retardant
biobased materials
flame retardance
flexible
phenolic resin
condensed phase
aluminum diethylphosphinate
PLA
melamine triazine
chain extension
EVA/LLDPE blend
reactive flame retardancy
dielectric constant
clay
composites
ammonium polyphosphate
phosphorus-containing flame retardant
flame retardancy
calorimetry
pyrolysis–combustion flow calorimetry
fire reaction
DOPO
van Krevelen approach
melamine
wire and cable
cotton fabrics
organophosphorus compounds
flame-retardant
lignin nanoparticles
polylactide
group contributions
bic Book Industry Communication::G Reference, information & interdisciplinary subjects::GP Research & information: general
topic_facet Q1-390
QC1-999
nano-SiO2
polymer flammability
biodegradable
fracture toughness
microcalorimetry of combustion
lignin
ZIF-8@GO hybrids
poly(3-hydroxybutyrate) (PHB)
biomaterials
epoxy novolac resin
phosphorylation
PLA ROP
thermal decomposition
polyamide 11
flame retardant
biobased materials
flame retardance
flexible
phenolic resin
condensed phase
aluminum diethylphosphinate
PLA
melamine triazine
chain extension
EVA/LLDPE blend
reactive flame retardancy
dielectric constant
clay
composites
ammonium polyphosphate
phosphorus-containing flame retardant
flame retardancy
calorimetry
pyrolysis–combustion flow calorimetry
fire reaction
DOPO
van Krevelen approach
melamine
wire and cable
cotton fabrics
organophosphorus compounds
flame-retardant
lignin nanoparticles
polylactide
group contributions
bic Book Industry Communication::G Reference, information & interdisciplinary subjects::GP Research & information: general
url 44788
work_keys_str_mv AT laoutidfouad advancedflameretardantmaterials