Coupling Nanofibril Lateral Size and Residual Lignin to Tailor the Properties of Lignocellulose Films

Lignocellulosic nanofibrils (LCNF) are produced from a single source of unbleached, oxidized wood fibers by serial disintegration, high‐pressure microfluidization, and homogenization. Sequential centrifugation enables fractionation by fibril width (≈5, ≈9, and ≈18 nm). LCNF residual lignin of high m...

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Bibliographic Details
Published in:Advanced materials interfaces 2019-10, Vol.6 (19), p.n/a
Main Authors: Imani, Monireh, Ghasemian, Ali, Dehghani‐Firouzabadi, Mohammad Reza, Afra, Elyas, Borghei, Maryam, Johansson, Leena S., Gane, Patrick A. C., Rojas, Orlando J.
Format: Article
Language:English
Subjects:
Coupling (molecular)
Disintegration
Fractionation
Free energy
Hot pressing
Hydroxyl groups
Interstices
light transmission
Lignin
Lignocellulose
lignocellulose nanofibrils
Mechanical properties
microfluidization
Modulus of elasticity
Porosity
Surface energy
Surface roughness
Wood fibers
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Summary:Lignocellulosic nanofibrils (LCNF) are produced from a single source of unbleached, oxidized wood fibers by serial disintegration, high‐pressure microfluidization, and homogenization. Sequential centrifugation enables fractionation by fibril width (≈5, ≈9, and ≈18 nm). LCNF residual lignin of high molecular mass reports together with the finest fraction (LCNF‐fine), whereas the more strongly cellulose‐bound lignin, of relatively lower molecular mass, associates with the coarsest fraction (LCNF‐coarse). Hot pressing softens the amorphous lignin, which fills the interstices between fibrils and acts as an in‐built interfacial cross‐linker. Thus, going from the LCNF‐fine to the LCNF‐course films, it is possible to obtain a range of values for the structural consolidation (density from 0.9 to 1.2 g cm−3 and porosity from 19% to 40%), surface roughness (RMS from ≈6 to 13 nm), and strength (elastic modulus from 8 to ≈12 GPa). The concentration of free hydroxyl groups controls effectively the direct surface interactions with liquids. The apparent surface energy dispersive component tracks with the total surface free energy and appears to be strongly influenced by the higher porosity as the fibril lateral size increases. The results demonstrate the possibility to tailor nanofibril cross‐linking and associated optical and thermo‐mechanical performance of LCNF films. A single fiber source is subjected to sequential fractionation to produce high yield nanocelluloses of different widths and residual lignin. The lignin content (bulk and surface) as well as molecular mass is coupled to the fibril lateral dimensions. Such features are exploited to adjust the structural and thermomechanical properties of thin films that can be derived from used paper and recycled fibers.
ISSN:2196-7350
2196-7350
DOI:10.1002/admi.201900770