Enzymatic Hydrolysis Combined with Mechanical Shearing and High-Pressure Homogenization for Nanoscale Cellulose Fibrils and Strong Gels

Pääkkö, Marjo; Ankerfors, Mikael; Kosonen, Harri; Nykänen, Antti; Ahola, Sakari; Österberg, Monika; Ruokolainen, Janne; Laine, Janne; Larsson, Per Tomas; Ikkala, Olli; Lindström, Tom

doi:10.1021/bm061215p

Cited by 1,743 publications

(880 citation statements)

References 33 publications

Supporting

Mentioning

808

Contrasting

Unclassified

Order By: Relevance

“…The critical concentration for gel formation is inversely proportional to fibre axial ratio a/l (diameter to length) Hill 2008;Lasseuguette et al 2008). Furthermore, the rigidity of the elastic gel network at rest (G', from a frequency sweep spectrum) above the percolation limit is scaled following the power law Pääkkö et al 2007;Hill 2008;Agoda-Tandjawa et al 2010), G 0 / ku a , where the factor k depends on axial ratio , k / ða=lÞ 2 , and exponent a on fibril volume fraction (Hill 2008), a / u.…”

Section: Introductionmentioning

confidence: 99%

Flocculated flow of microfibrillated cellulose water suspensions: an imaging approach for characterisation of rheological behaviour

et al. 2012

View full text Add to dashboard Cite

Our aim was to characterise the suspension rheology of microfibrillated cellulose (MFC) in relation to flocculation of the cellulose fibrils. Measurements were carried out using a rotational rheometer and a transparent cylindrical measuring system that allows combining visual information to rheological parameters. The photographs were analyzed for their floc size distribution. Conclusions were drawn by comparing the photographs and data obtained from measurements. Variables selected for examination of MFC suspensions were degree of disintegration of fibres into microfibrils, the gap between the cylinders, sodium chloride concentration, and the effects of changing shear rate during the measurement. We studied changes in floc size under different conditions and during network structure decomposition. At rest, the suspension consisted of flocs sintered together into a network. With shearing, the network separated first into chain-like floc formations and, upon further shear rate increase, into individual spherical flocs. The size of these spherical flocs was inversely proportional to the shear rate. Investigations also confirmed that floc size depends on the geometry gap, and it affects the measured shear stress. Furthermore, suspension photographs revealed an increasing tendency to aggregation and wall depletion with sodium chloride concentration of 10 -3 M and higher.

show abstract

Section: Introductionmentioning

confidence: 99%

Flocculated flow of microfibrillated cellulose water suspensions: an imaging approach for characterisation of rheological behaviour

et al. 2012

View full text Add to dashboard Cite

show abstract

“…The mixture and NFC were shear thinning, which has also earlier been observed for pure NFC dispersions. 48 Finally, we point out that the high viscosity values shown in Figure 4b suggested us to use low concentrations to prepare the mixtures, in order to obtain homogeneous mixtures even at very high NFC-to-chitosan ratios. 49 Mechanical properties.…”

Section: Resultsmentioning

confidence: 96%

Water-Resistant, Transparent Hybrid Nanopaper by Physical Cross-Linking with Chitosan

et al. 2015

View full text Add to dashboard Cite

ABSTRACT. One of the major, but often overlooked, challenges towards high end applications of nanocelluloses is to maintain their mechanical stability under hydrated conditions. As such, permanent covalent crosslinking or surface hydrophobization are viable solutions provided that neither processability nor interfibrillar bonding is compromised. Here we show an alternative based on physical crosslinking of nanofibrillated cellulose (NFC, also denoted as microfibrillated cellulose, MFC, and cellulose nanofibers, CNF) with chitosan for the preparation of transparent films. Transparency (~ 80 % throughout the visible spectrum) is achieved by suppressing aggregation and carefully controlling the mixing conditions: Chitosan dissolves in aqueous medium at low pH and under these conditions the NFC/chitosan mixtures form easily processable hydrogels.A simple change in the environmental conditions (i.e. an increase of pH) reduces hydration of chitosan promoting multivalent physical interactions between NFC and chitosan over those with water, resulting effectively in crosslinking. Films of NFC/chitosan 80/20 w/w show excellent mechanical properties in the wet state, with a tensile modulus of 4 and 14 GPa at low (0.5 %) and large (16 %) strains, respectively and an ultimate strength of 100 MPa (with corresponding maximum strain of 28 %). Remarkably, a strength of 200 MPa (with maximum strain of 8%) is measured at 50 % air relative humidity. We expect that the proposed, simple concept opens new pathways toward NFC-based material utilization in wet or humid conditions, a challenge that has remained unresolved.

show abstract

“…The enzyme treatment can also be carried out at quite low enzyme concentration. 14 The subsequent procedure for mechanical homogenization disintegrates the cell wall into nanofibrils by subjecting dilute wood fiber suspensions to high shear forces. The homogenization method to produce mirofibrillated cellulose was originally developed by Herrick et al 15 and Turbak et al 16 Recently, we studied nanocomposites consisting of a wood cellulose nanofibril network in a plasticized potato starch matrix.…”

Section: Introductionmentioning

confidence: 99%

Cellulose Nanopaper Structures of High Toughness

et al. 2008

View full text Add to dashboard Cite

Cellulose nanofibrils offer interesting potential as a native fibrous constituent of mechanical performance exceeding the plant fibers in current use for commercial products. In the present study, wood nanofibrils are used to prepare porous cellulose nanopaper of remarkably high toughness. Nanopapers of different porosities and from nanofibrils of different molar mass are prepared. Uniaxial tensile tests are performed and structure-property relationships are discussed. The high toughness of highly porous nanopaper is related to the nanofibrillar network structure and high mechanical nanofibril performance. Also, molar mass correlates with tensile strength. This indicates that nanofibril fracture controls ultimate strength. Furthermore, the large strain-to-failure means that mechanisms, such as interfibril slippage, also contributes to inelastic deformation in addition to deformation of the nanofibrils themselves.

show abstract

Enzymatic Hydrolysis Combined with Mechanical Shearing and High-Pressure Homogenization for Nanoscale Cellulose Fibrils and Strong Gels

Cited by 1,743 publications

References 33 publications

Flocculated flow of microfibrillated cellulose water suspensions: an imaging approach for characterisation of rheological behaviour

Flocculated flow of microfibrillated cellulose water suspensions: an imaging approach for characterisation of rheological behaviour

Water-Resistant, Transparent Hybrid Nanopaper by Physical Cross-Linking with Chitosan

Cellulose Nanopaper Structures of High Toughness

Contact Info

Product

Resources

About