Abstract

In this paper, we reported on environmental technique of developing for the deposition of silver nanoparticles onto polyamide (PA) fibers. A new composite PA yarn with carboxyl methyl starch (CMS) including silver nanoparticles (AgNPs) has been synthesized. The influence of silver nitrate concentration on the morphological and spectrophometeric properties was investigated. SEM images showed the distribution of silver nanoparticles and nanolayer formation on the surface. Electrical conductivity of composite yarns was measured by four point probe technique and was changed from 1.574x10-7 to 2.630x10-4 S/cm. The antibacterial activities of the composite yarns have been investigated against Escherichia coli and determined considerable antibacterial properties.

References

[1] Dong C., Zhang X., Cai H., Cao C., Facile and one-step synthesis of monodisperse silvernanoparticles using gum acacia in aqueous solution, Journal of Molecular Liquids 196 (2014)135–141.
[2] Mulongo G., Mbabazi J. and Hak-Chol S., Synthesis and Characterisation of SilverNanoparticles using High Electrical Charge Density and High Viscosity Organic Polymer,Research Journal of Chemical Sciences, Vol. 1(4), 18-21, July (2011).
[3] Hebeish A., El-Rafie M. H., El-Sheikh M. A, and Mehrez E. El-Naggar, NanostructuralFeatures of Silver Nanoparticles Powder Synthesized through Concurrent Formation of theNanosized Particles of Both Starch and Silver, Journal of Nanotechnology, Volume 2013,Article ID 201057, 10 pages http://dx.doi.org/10.1155/2013/201057
[4] Zhang X.F., Liu Z.G, Shen W., Gurunathan S., (2016). Silver Nanoparticles: Synthesis,Characterization, Properties, Applications, and Therapeutic Approaches, Int J Mol Sci. Sep;17(9): 1534.
[5] Babaahmadi V., Montazer M., (2015). New route to synthesis silver nanoparticles onpolyamide fabric using stannous chloride, The Journal of The Textile Institute, 106:9, 970-977, DOI: 10.1080/00405000.2014.957468.
[6] Montazer M. Komeily Nia Z., Conductive nylon fabric through in situ synthesis of nanosilver: Preparation and characterization, Materials Science and Engineering C 56 (2015) 341–347.
[7] Alshehri S. M., Aldalbahi A., Baker Al-hajji A., Chaudhary A.A., Panhuis M., AlhokbanyN., Ahamad T., Development of carboxymethyl cellulose-based hydrogel andnanosilvercomposite as antimicrobial agents for UTI pathogens, 2015, Carbohydrate Polymers 138 -2016- 229–236.
[8] Xue, C.H., Chen J., Yin W., Tian Jia S., J. Zhong M, Superhydrophobic conductive textileswith antibacterial property by coating fibers with silver nanoparticles a College of Resourceand Environment Chemistry and Technology for Light Chemical Industry, Ministry ofEducation, Shaanxi University of Science and Technology,2012.
[9] Montazer M., Nia Z.K., Conductive nylon fabric through in situ synthesis of nano-silver:Preparation and characterization, Materials Science and Engineering C 56, 2015; 341–347.
[10] Ashayer Soltani R., Hunt C., Thomas O., Fabrication of highly conductive stretchable textilewith silver nanoparticles, Textile Research Journal 2016, Vol. 86(10) 1041–1049
[11] Ortega F., Giannuzzi L., Arce V.B., Alejandra García M., Active composite starch filmscontaining green synthetized silver nanoparticles, Food Hydrocolloids 70 (2017) 152e162.
[12] Abdel-Halima E.S., H. Alanazia H., S. Al-Deyab S., Utilization of hydroxypropylcarboxymethyl cellulose in synthesis of silver nanoparticles, International Journal ofBiological Macromolecules 75 (2015) 467–473.
[13] Kanmani P., Taik Lim S., Synthesis and characterization of pullulan-mediated silvernanoparticles and its antimicrobial activities, Carbohydrate Polymers 97 (2013) 421– 428.
[14] Van der Pauw, L. J. “A Method of Measuring Specific Resistivity and Hall Effect of Discsof Arbitrary Shape.” Philips Research Reports 12.1 (1958): 1-9. Print.
[15] G. Guzmán M., Dille J., Godet S., Synthesis of silver nanoparticles by chemical reductionmethod and their antibacterial activity, 2009, International Journal of Chemical andBiomolecular Engineering 2:3 2009.