Promising grafting strategies on cellulosic backbone through radical polymerization processes – A review

[Display omitted] •Formulation of cellulosic derivative by exploiting radical polymerization method (RPM) is discussed.•Activation of cellulosic texture has been described.•Monomer’s grafting onto cellulosic texture from suitable initiators have been elaborated.•Radiation indulged system promote the...

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Bibliographic Details
Published in:European polymer journal 2021-06, Vol.152, p.110448, Article 110448
Main Authors: Kumar, Maneesh, Gehlot, Praveen Singh, Parihar, Deepika, Surolia, Praveen K., Prasad, Gayatri
Format: Article
Language:English
Subjects:
Backbone
Biodegradability
Butadiene
Cellulose
Cerium ammonium nitrate
Chemical properties
Chemical synthesis
Controlled radical polymerization
Free radicals
Gamma rays
Grafting
Initiators
Lithium-ion batteries
Methacrylamide
Natural polymers
Paper board
Photoinitiators
Photovoltaic cells
Polymer composite
Polymer matrix composites
Polymerization
Polymers
Potassium persulfate
Radiation technique
Radical polymerization
Reagents
Rechargeable batteries
Separators
Solar cells
Tensile strength
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Summary:[Display omitted] •Formulation of cellulosic derivative by exploiting radical polymerization method (RPM) is discussed.•Activation of cellulosic texture has been described.•Monomer’s grafting onto cellulosic texture from suitable initiators have been elaborated.•Radiation indulged system promote the performance of RPM.•Controlled radical polymerization triggers the cellulose grafting reaction in block polymerization style. Cellulose is an abundant organic substance found in natural polymer, consists of a linear chain of β glucose residue, which ties from the 1, 4 linkage. Owing to their incredible properties such as bio-renewable, specific tensile strength and bio-degradable, it is being enormously using as a paperboard, drug delivery, fiber production, food packing material, sensitized solar cell, biosorbent, pickering emulsion stabilizer, and battery separator in the modern age of the lithium-ion battery. This review principally points out the radical polymerization method (RPM) for fabricating cellulose derivative. By exploiting RPM, new and improved properties indulging polymer composite of cellulose can successfully fix up by the reaction with the small organic fragment (monomer) such as a methacrylate, methacrylamide, styrene, and butadiene, etc. Radical polymerization has been striking for a long time, due to their procurable process-ability among all the polymerization methods. The most commonly used initiators such as Fenton's reagent, potassium persulfate, and ceric ammonium nitrate are being using to engender free radicals on the cellulose backbone. Other free radical generating techniques like radiation technique (UV + photoinitiator, gamma radiation), plasma treatment, and controlled radical polymerization are being using for grafting purposes. The review summarizes to traditional grafting strategy by common initiators and currently utilizing controlled radical polymerization (CRP) chemistry for polymer synthesis. These methods allow for the formation of functional cellulose, which may possess renovated physical and chemical properties.
ISSN:0014-3057
1873-1945
DOI:10.1016/j.eurpolymj.2021.110448