Fabrication and applications of cellulose nanoparticle-based polymer composites.(Report): An article from: Polymer Engineering and Science
Book Details
PublisherSociety of Plastics Engineers, Inc.
ISBN / ASINB00B45EBAA
ISBN-13978B00B45EBA5
MarketplaceIndia 🇮🇳
Description
This digital document is an article from Polymer Engineering and Science, published by Society of Plastics Engineers, Inc. on January 1, 2013. The length of the article is 5379 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available immediately after purchase. You can view it with any web browser.
From the author: The impressive mechanical properties, reinforcing capability, abundance, low weight, low filler load requirements, and biodegradable nature of nanopartidies from bioresources such as cellulose, make it an ideal candidate for the development of green polymer nanocomposites. Significant amount of research in this area is primarily focused on the extraction, qualitative surface modification, and evaluation of mechanical performance after filling in polymer matrixes at different ratios. The extreme agglomeration tendency, hydrophilic nature, difficult dispersion in many organic solvents of cellulose nanoparticles are the challenging obstacles when fabrication of such nanocomposites is concerned. Traditional processing of polymer composites mainly through extrusion and melt compounding, is not easily possible in case of cellulose nanocomposites due to higher possibility of poor dispersion and degradation of nanofibers. Therefore, issues related to the fabrication of nanofiber-based products and their application appears to be one of the most important areas in order to enhance their competitiveness with other nanoparticles. This review is aimed to summarize the recent accomplishments and issues involving the use of cellulose nanoparticles in the development of new polymeric materials. POLYM. ENG. SCI., 53:1-8, 2013. [C] 2012 Society of Plastics Engineers
Citation Details
Title: Fabrication and applications of cellulose nanoparticle-based polymer composites.(Report)
Author: Jitendra K. Pandey
Publication:Polymer Engineering and Science (Magazine/Journal)
Date: January 1, 2013
Publisher: Society of Plastics Engineers, Inc.
Volume: 53 Issue: 1 Page: 1(8)
Article Type: Report
Distributed by Gale, a part of Cengage Learning
From the author: The impressive mechanical properties, reinforcing capability, abundance, low weight, low filler load requirements, and biodegradable nature of nanopartidies from bioresources such as cellulose, make it an ideal candidate for the development of green polymer nanocomposites. Significant amount of research in this area is primarily focused on the extraction, qualitative surface modification, and evaluation of mechanical performance after filling in polymer matrixes at different ratios. The extreme agglomeration tendency, hydrophilic nature, difficult dispersion in many organic solvents of cellulose nanoparticles are the challenging obstacles when fabrication of such nanocomposites is concerned. Traditional processing of polymer composites mainly through extrusion and melt compounding, is not easily possible in case of cellulose nanocomposites due to higher possibility of poor dispersion and degradation of nanofibers. Therefore, issues related to the fabrication of nanofiber-based products and their application appears to be one of the most important areas in order to enhance their competitiveness with other nanoparticles. This review is aimed to summarize the recent accomplishments and issues involving the use of cellulose nanoparticles in the development of new polymeric materials. POLYM. ENG. SCI., 53:1-8, 2013. [C] 2012 Society of Plastics Engineers
Citation Details
Title: Fabrication and applications of cellulose nanoparticle-based polymer composites.(Report)
Author: Jitendra K. Pandey
Publication:Polymer Engineering and Science (Magazine/Journal)
Date: January 1, 2013
Publisher: Society of Plastics Engineers, Inc.
Volume: 53 Issue: 1 Page: 1(8)
Article Type: Report
Distributed by Gale, a part of Cengage Learning
