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Molecular-level design of alternative media for energy-saving pilot-scale fibrillation of nanocellulose. | LitMetric

AI Article Synopsis

  • - The study explores the potential of cellulose nanofibrils (CNFs) as eco-friendly materials, highlighting their lightweight and biodegradable properties, making them suitable for next-generation composites and bioplastics.
  • - Atomistic molecular dynamics simulations identified a NaOH and urea aqueous solution as an effective medium to reduce energy consumption during CNF production by about 21% compared to water, while maintaining similar properties.
  • - The findings suggest a new approach for dispersing deprotonable polymers in manufacturing processes, combining computer simulations with pilot-scale experiments to enhance efficiency in the bioeconomy.

Article Abstract

The outstanding mechanical properties, light weight, and biodegradability of cellulose nanofibrils (CNFs) make them promising components of renewable and sustainable next-generation reinforced composite biomaterials and bioplastics. Manufacturing CNFs at a pilot scale requires disc-refining fibrillation of dilute cellulose fibers in aqueous pulp suspensions to shear the fibers apart into their nanodimensional forms, which is, however, an energy-intensive process. Here, we used atomistic molecular dynamics (MD) simulation to examine media that might facilitate the reduction of interactions between cellulose fibers, thereby reducing energy consumption in fibrillation. The most suitable medium found by the simulations was an aqueous solution with 0.007:0.012 wt.% NaOH:urea, and indeed this was found in pilot-scale experiments to reduce the fibrillation energy by ~21% on average relative to water alone. The NaOH:urea-mediated CNFs have similar crystallinity, morphology, and mechanical strength to those formed in water. The NaOH and urea act synergistically on CNFs to aid fibrillation but at different length scales. NaOH deprotonates hydroxyl groups leading to mesoscale electrostatic repulsion between fibrils, whereas urea forms hydrogen bonds with protonated hydroxyl groups thus disrupting interfibril hydrogen bonds. This suggests a general mechanism in which an aqueous medium that contains a strong base and a small organic molecule acting as a hydrogen-bond acceptor and/or donor may be effectively employed in materials processes where dispersion of deprotonable polymers is required. The study demonstrates how atomic-detail computer simulation can be integrated with pilot-scale experiments in the rational design of materials processes for the circular bioeconomy.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11406261PMC
http://dx.doi.org/10.1073/pnas.2405107121DOI Listing

Publication Analysis

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