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Conversion of Cellulose and Lignin Residues into Transparent UV-Blocking Composite Films
Summary
Researchers developed UV-blocking composite films by chemically converting cellulose and lignin residues from three biomass sources (aspen wood, poplar wood, and corn stover) via a dissolution-regeneration process, assessing their UV-blocking performance as a sustainable alternative to petrochemical plastic films. Results showed that all three lignin residue types enhanced the UV-blocking properties of the composite films, supporting their potential in functional biorefinery-integrated packaging.
The valorization of cellulose and lignin residues in an integrated biorefinery is of great significance to improve the overall economics but has been challenged by their structural recalcitrance, especially for lignin residue. In this work, a facile chemical conversion route to fabricating functional UV-blocking cellulose/lignin composite films through a facile dissolution-regeneration process using these biomass residues was proposed. Three representative lignin residues, i.e., aspen and poplar wood lignin, and corn stover (CS) lignin were assessed for their feasibility for the film fabrication. The UV-blocking performance of the composite films were comparatively investigated. Results showed that all these three lignin residues could enhance the UV-blocking property of the composite films, corresponding to the reduction in the optical energy band gap from 4.31 to 3.72 eV, while poplar lignin had a considerable content of chromophores and showed the best UV-blocking enhancement among these three assessing lignins. The enhancement of UV-blocking property was achieved without compromising the visible-light transparency, mechanical strength and thermal stability of the composite films even at 4% lignin loading. This work showed the high promise of integrating biomass residue conversion into lignocellulose biorefinery for a multi-production purpose.
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