Abstract
Micro- and nanocelluloses are typically produced using intensive mechanical treatments such as grinding, milling or refining followed by high-pressure homogenization to liberate individual nano- and microcellulose fragments. Even though chemical and enzymatic pretreatments can be used to promote fiber disintegration, the required mechanical treatments are still highly energy consuming and very costly. Therefore, it is important to understand the kinetics and factors affecting the disintegration tendency of cellulose. In this study, the disintegration tendency of three different wood cellulose pulps with varying chemical composition processed in a PFI mill was examined by analyzing the fractional composition of the microparticles formed. The fractional compositions of the microfibrils and microparticles formed were measured with novel analyzers, which fractionated particles using a continuous water flow in a long tube. The hydrodynamic fractionators used in this study gave valuable information about different size of particles. Results showed that the amount of lignin and hemicelluloses clearly affected the kinetics and the mechanics of cellulose degradation. The P and S1 layers were peeled off from the Kraft fibers, causing the S2 layer to be cropped out. The thermomechanical pulp (TMP) fibers were first degraded by comminution and delamination from the middle lamella and the primary wall. As the refining process progressed, the fibers and fiber fragments began to unravel. Surprisingly, the semi-chemical pulp (SCP) fibers degraded more like Kraft fibers than TMP fibers despite their high lignin and extractive content.
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Baiardo M, Frisoni G, Scandola M, Licciardello A (2002) Surface chemical modification of natural cellulose fibers. J Appl Polym Sci 83:38–45
Fardim P, Holmbom B, Ivaska A, Karhu J, Mortha G, Laine J (2002) Critical comparison and validation of methods for determination of anionic groups in pulp fibres. Nord Pulp Pap Res J 17(3):346–351
Forgacs OL (1963) The characterization of mechanical pulps. Pulp Pap Mag Can 64(C):T89–T116
Horvath AE, Lindström T (2007) The influence of colloidal interactions on fiber network strength. J Collid Interface Sci 309:511–517
Karnis A (1994) The mechanism of fibre development in mechanical pulping. J Pulp Pap Sci 20(10):J280–J288
Kleen M, Kangas H, Laine C (2003) Chemical characterization of mechanical pulp fines and fiber surface layers. Nord Pulp Pap Res J 18(4):361–368
Klemm D, Kramer F, Moritz S, Lindström T, Ankerfors M, Gray D, Dorris A (2011) Nanocelluloses: a NRW family of nature-based materials. Angew Chem Int Ed 50:5438–5466
Krogerus B, Fagerholm K, Tiikkaja E (2002) Fines from different pulps compared by image analysis. Nord Pulp Pap Res J 17(4):440–444
Laine J, Buchert J, Viikari L, Stenius P (1996) Characterization of unbleached Kraft pulps by enzymatic treatment, potentiometric titration and polyelectrolyte adsorption. Holzforschung 50:208–214
Laitinen O (2011) Utilisation of tube flow fractionation in fibre and particle analysis. Doctoral thesis, Department of Process and Environmental Engineering, University of Oulu, Finland
Le Moigne N, Jardeby K, Navard P (2010) Structural changes and alkaline solubility of wood cellulose fibers after enzymatic peeling treatment. Carbohyd Polym 79:325–332
Luukko K (1998) On the characterization of mechanical pulp fines—A review. Paperi ja Puu (Paper and Timber) 80(6):441–448
Luukko K, Kemppainen-Kajola P, Paulapuro H (1997) Cheracterization of mechanical pulp fines by image analysis. Appita J 50(5):387–392
Luukko K, Laine J, Pere J (1999) Chemical characterization of different mechanical pulp fines. Appita J 52(2):126–131
Molin U, Daniel G (2004) Effects of refining on the fibre structure of kraft pulps as revealed by FE-SEM and TEM: influence of alkaline degradation. Holzforschung 58:226–232
Mosbye J, Moe S, Laine J (2001) The charge of fines originating from different parts of the fibre wall. ISWPC 11th international symposium on wood and pulping chemistry, Nice (France), 11–14, June, 2001, pp 169–172
Nagaito AN, Yano H (2004) The effect of morphological changes from pulp fiber towards nano-scale fibrillated cellulose on the mechanical properties of high-strength plant fiber based composites. Appl Phys A 78:547–552
Nakagaito AN, Yano H (2005) Novel high-strength biocomposites based on microfibrillated cellulose having nano-order-unit web-like network structure. Appl Phys A 80:155–159
Nyström G, Mihranyan A, Razaq A, Lindström T, Nyholm L, Strømme M (2010) A nanocellulose polypyrrole composite based on microfibrillated cellulose from wood. J Phys Chem B 114:4178–4182
Saito T, Kimura S, Nishiyama Y, Isogai A (2007) Cellulose nanofibers prepared by TEMPO-mediated oxidation of native cellulose. Biomacromolecules 8:2485–2491
Salmén L, Olsson A-M (1998) Interaction between hemicelluloses, lignin and cellulose: structure-property relationships. J Pulp Pap Sci 24(3):99–103
Siró I, Plackett D (2010) Microfibrillated cellulose and new nanocomposite materials: a review. Cellulose 17:459–494
Spence KL, Venditti RA, Rojas OJ, Habibi Y, Pawlak JJ (2010a) The effect of chemical composition on microfibrillar cellulose films from wood pulps: mechanical processing and physical properties. Bioresour Technol 101:5961–5968
Spence KL, Venditti RA, Rojas OJ, Habibi Y, Pawlak JJ (2010b) The effect of chemical composition on microfibrillar cellulose films from wood pulps: water interactions and physical properties for packaging applications. Cellulose 17:835–848
Stevanic JS, Salmén L (2009) Orientation of the wood polymers in the cell wall of spruce wood fibres. Holzforschung 63:497–503
Sundberg A, Holmbom B (2004) Fines in spruce TMP, BTMP and CTMP- chemical composition and sorption of mannans. Nord Pulp Pap Res J 19(2):176–182
Sundberg A, Sundberg K, Lillandt C, Holmbom B (1996) Determination of hemicelluloses and pectins in wood and pulp fibers by acid methanolysis and as chromatography. Nord Pulp Pap Res J 11:216–219
Sundberg A, Pranovich AV, Holmbom B (2003) Chemical characterization of various types of mechanical pulp fines. J Pulp Pap Sci 29(5):173–178
Taniguchi T, Okamura K (1998) New films produced from microfibrillated natural fibres. Polym Int 47:291–294
Turbak AF, Snyder FW, Sandberg KR (1983) Microfibrillated cellulose, a new cellulose product: properties, uses, and commercial potential. J Appl Polym Sci Appl Polym Symp 37:815–827
Wang X, Maloney T C, Paulapuro H (2007) Fibre fibrillation and its impact on sheet properties. Paperi ja Puu (Paper and Timber) 88(7):409–411
Zhang W, Liang M, Lu C (2007) Morphological and structural development of hardwood cellulose during mechanochemical pretreatment in solid state through pan-milling. Cellulose 14:447–456
Zimmermann T, Pöhler E, Geiger T (2004) Cellulose fibrils for polymer reinforcement. Adv Eng Mat 6(9):754–761
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Suopajärvi, T., Liimatainen, H. & Niinimäki, J. Fragment analysis of different size-reduced lignocellulosic pulps by hydrodynamic fractionation. Cellulose 19, 237–248 (2012). https://doi.org/10.1007/s10570-011-9615-y
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DOI: https://doi.org/10.1007/s10570-011-9615-y