Engineering physical and chemical properties of softwood kraft lignin by fatty acid substitution

This research focuses on the chemical modification of lignin with stearate of controlled degree of substitution. [Display omitted] •A method to graft fatty acids to lignin was carried out to improve the processability of lignin.•A large window of products with controlled degree of substitution could...

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Bibliographic Details
Published in:Industrial crops and products 2016-10, Vol.89, p.128-134
Main Authors: Pawar, Siddhesh N., Venditti, Richard A., Jameel, Hasan, Chang, Hou-Min, Ayoub, Ali
Format: Article
Language:English
Subjects:
crystallization
Fatty acid
Glass transition
heat
Lignin
Melting
nuclear magnetic resonance spectroscopy
physicochemical properties
polystyrenes
Softwood
stearic acid
temperature
thermal properties
thermoplastics
Wood products
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Summary:This research focuses on the chemical modification of lignin with stearate of controlled degree of substitution. [Display omitted] •A method to graft fatty acids to lignin was carried out to improve the processability of lignin.•A large window of products with controlled degree of substitution could be achieved. A 1H NMR method was developed for quantification of the degree of substitution.•Interesting physical properties were observed with lignin stearates found to melt at temperatures as low as 50ºC. A process to attach fatty acids to lignin is reported which alters its thermal behavior. By attaching saturated C18 fatty acids to OH groups, stable lignin stearates (LS) of controllable degrees of substitution (DS) were synthesized. Interesting physical properties were observed, wherein LS was observed to melt and flow at temperatures as low as 50°C. Melting was possible due to the crystallization of stearate chains when LS was purified by precipitation. A NMR method was established for quantification of the degree of substitution. At very high %DS values (close to 100%), the melting phenomenon was reversible, but at low %DS, melting occurred only during the 1st heating ramp during thermal cycling. The ability of LS to plasticize polystyrene (PS) is reported wherein integral blend films containing up to 25% by weight of LS were formed. The Tg of the blended films could be lowered by 22°C using LS relative to PS. Lignin stearates have the potential to serve as interesting compounds for their ability to plasticize not only PS but other thermoplastic materials as well.
ISSN:0926-6690
1872-633X
DOI:10.1016/j.indcrop.2016.04.070