Fabrication of flame retardant lyocell fibers based on carboxymethylation and aluminum ion chelation

[1] Abdelhameed RM(2018)Efficient removal of organophosphorus pesticides from wastewater using polyethylenimine-modified fabrics Polymer 155 225-234

[2] El-Zawahry M(2017)Self-assembled AuNPs for ingrain pigmentation of silk fabrics with antibacterial potency Int J Biol Macromol 105 720-729

[3] Emam HE(2018)Nanosilver leverage on reactive dyeing of cellulose fibers: Color shading, color fastness and biocidal potentials Carbohyd Polym 186 310-320

[4] Ahmed HB(2011)Hydrotalcite and nanometric silica as finishing additives to enhance the thermal stability and flame retardancy of cotton Cellulose 18 179-190

[5] El-Hawary NS(2015)Cotton flame retardancy: state of the art and future perspectives RSC Adv 5 24239-24263

[6] Emam HE(2014)Sol-gel derived architectures for enhancing cotton flame retardancy: effect of pure and phosphorus-doped silica phases Polym Degrad Stab 99 92-98

[7] Ahmed HB(2019)Superior flame retardancy of cotton by synergetic effect of cellulose-derived nano-graphene oxide carbon dots and dilulphide-containing polyamidoamines Polym Degrad Stab 169 108993-69

[8] Emam HE(2017)Preparation and characterization of biodegradable nanocomposites derived from carboxymethyl cellulose and hydroxyapatite Carbohyd Polym 167 59-228

[9] Mashaly HM(2014)Improved flame retardant properties of lyocell fiber achieved by phosphorus compound Mater Lett 135 226-323

[10] Rehan M(2013)Ion-interactions as driving force in polysaccharide assembly Carbohyd Polym 93 316-12167

[1] Abdelhameed RM(2018)Efficient removal of organophosphorus pesticides from wastewater using polyethylenimine-modified fabrics Polymer 155 225-234

[2] El-Zawahry M(2017)Self-assembled AuNPs for ingrain pigmentation of silk fabrics with antibacterial potency Int J Biol Macromol 105 720-729

[3] Emam HE(2018)Nanosilver leverage on reactive dyeing of cellulose fibers: Color shading, color fastness and biocidal potentials Carbohyd Polym 186 310-320

[4] Ahmed HB(2011)Hydrotalcite and nanometric silica as finishing additives to enhance the thermal stability and flame retardancy of cotton Cellulose 18 179-190

[5] El-Hawary NS(2015)Cotton flame retardancy: state of the art and future perspectives RSC Adv 5 24239-24263

[6] Emam HE(2014)Sol-gel derived architectures for enhancing cotton flame retardancy: effect of pure and phosphorus-doped silica phases Polym Degrad Stab 99 92-98

[7] Ahmed HB(2019)Superior flame retardancy of cotton by synergetic effect of cellulose-derived nano-graphene oxide carbon dots and dilulphide-containing polyamidoamines Polym Degrad Stab 169 108993-69

[8] Emam HE(2017)Preparation and characterization of biodegradable nanocomposites derived from carboxymethyl cellulose and hydroxyapatite Carbohyd Polym 167 59-228

[9] Mashaly HM(2014)Improved flame retardant properties of lyocell fiber achieved by phosphorus compound Mater Lett 135 226-323

[10] Rehan M(2013)Ion-interactions as driving force in polysaccharide assembly Carbohyd Polym 93 316-12167