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2024 | OriginalPaper | Chapter

6. The Fiber Cell Wall

Author : Vail Manfredi

Published in: Eucalyptus Kraft Pulp Refining

Publisher: Springer Nature Switzerland

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Abstract

In this chapter, the multilayered fibrillar structure of the fiber cell wall is presented, with discussions focusing on the structural modifications (fibrillations) caused by the refining action. The intensity and amount of these structural changes in the fiber wall determine the degree of refining, attributing the desired characteristics to the paper produced.

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Whitney, R. P. – The dtory of paper. Tappi Press, Atlanta, 1984, 28 pgs.

Scott, W. E., Abbott, J. C. and Trosset, S. – Properties of paper: an introduction. Tappi Press, Atlanta. 191 pgs. (1995).

27.

Sorieul, M.; Dickson, A.; Hill, S. J. and Pearson, H. – Plant fibre: molecular structure and biomechanical properties, of a complex living material, influencing Its deconstruction towards a biobased composite. Materials, 9 (618): 1–36; (2016).

37.

Fahlén J, Salmén L. – Cross-sectional structure of the secondary wall of wood fibers as affected by processing. In: 11th International Symposium on Wood and Pulping Chemistry. Nice, 2001 pg. 585.

38.

Åkerholm, M. – Ultrastructural aspects of pulp fibers as studied by dynamic FT-IR spectroscopy. Doctoral Thesis. Royal Institute of Technology. Stockholm, 2003 71 pgs http://www.diva-portal.org/smash/get/diva2:9438/FULLTEXT01.pdf.

40.

Clarke, C. R. E.; Shaw, M. J. P.; Wessels, A. M. and Jones, W. R. – Effect of differences in climate on growth, wood, and pulp properties of nine eucalypt species at two sites. Tappi Journal, 82 (7): 89–99 (1999).

43.

Antolovich, E. – Method of treating bleached pulp on a washer with calcium ions to remove sodium ions. U.S. Patent no 5,273,625 (1993) https://patents.justia.com/patent/5273625.

47.

Lundqvist, S.O.; Grahn, T.; Hedenberg, O.; Hansen, P. – Visions and tools for forest and mill integration. Part 2: Some new approaches under development at STFI for prediction of paper properties. Eurofiber Seminar, STFI, Oral presentation. (2003). http://www.stfi.se/upload/3439/02_d14-3_stfi-lundqvist2_Part%202x.pdf

49.

Magaton, A. S.; Colodette, J. L.; Gouvea, A. F. G.; Gomide, J. L.; Muguet, M. C. S. and Pedrazzin, C. – Eucalyptus wood quality and its impact on kraft pulp production and use. Tappi Journal, 8 (8): 32–39 (2009).

57.

Foelkel, C. – Madeiras para uso celulósico-papeleiro: formação, ultraestrutura, química e topoquímica. Eucalyptus Newsletter (84) 645 pgs (2020) http://www.eucalyptus.com.br/news/pt_dez2020.pdf

69.

Ora, M. and Maloney. T. C. – The effect of moisture and structure on wet web strength and its variation – a pilot scale approach using dry and rewetted mill made papers. In: 15th Fundamental Research Symposyum, Cambridge, 2013 pgs. 71–100.

79.

Riki, J. T. B., Sotannde, O. A. and Oluwadare, A. O. – Anatomical and chemical properties of wood and their practical implictions in pulp and paper production – a review. Journal of Research in Forestry, Wildlife & Environment, 11 (3): 358–368 (2019).

102.

Philipp, P. and D’Almeida, M. L. O. – Celulose e papel – tecnologia de fabricação de papel – Volume 2. SENAI/IPT, São Paulo, 1988 402 pgs.

121.

Zhang, C.; Chen, M.; Keten, S.; Coasne, B.; Derome, D. and Carmeliet, J. – Hygromechanical mechanisms of wood cell wall revealed by molecular modeling and mixture rule analysis. Materials Science, 7 (37): eab8919 (2021).

143.

Chirat, C. and Lachenal, D. – Brushing up on bleaching techniques. Pulp & Paper International, 41 (10): 41–43 (1999).

190.

Pulkkinen, I. – From eucalypt fiber distributions to technical properties of paper. Doctoral Thesis. Aalto University School of Science and Technology, Espoo, 2010 74 pgs https://research.aalto.fi/en/publications/from-eucalypt-fiber-distributions-to-technical-properties-of-pape

191.

Courchene, C. E.; Peter, G. F. and Litvay, J. – Cellulose microfibril angle as a determinant of paper strength and hygroexpansivity in Pinus taeda L. Wood and Fiber Science, 38 (1): 112–120 (2006).

214.

Santos, A.; Anjos, O. M. and Simões, R. M. S. – Influence of kraft cooking conditions on the pulp quality of Eucalyptus globulus. Appita Journal, 61 (2): 148–155 (2008).

224.

Fergus, B. J.; Procter, A. R.; Scott, J. A. N. and Goring, D. A. I. – The distribution of lignin in spruce wood as determined by ultraviolet microscopy. Wood Science Technology (3): 117–138 (1969).

260.

Czibula, C.; Ganser, C.; Seidlhofer, T.; Teichert, C. and Hirn, U. – Transverse viscoelastic properties of pulp fibers investigated with an atomic force microscopy method. Journal of Mater Sciince, 54:11448–11461 (2019).

300.

Melander, E. – The effect of charged groups on the beatability of pulp fibres. Bachelor Thesis, KTH, Stockholm, 2011 31 pgs https://www.diva-portal.org/smash/get/diva2:425918/FULLTEXT01.pdf

329.

Alves, E. F.; Oliveira, R. C. de; Silva, L. H. M. da e Colodette, J. L. – Interação de fibras e elementos de vasos de polpa Kraft de eucalipto com tintas de impressão offset. In: XXXIX Congresso Anual. ABTCP. São Paulo, 2006 18 pgs.

370.

Yllner, S. and Enström, B. – Studies of the adsorption of xylan on cellulose fibers during the sulphate cook – Part 1. Svensk Papperistiding, 59 (6): 229–232 (1956).

406.

Foelkel, C – Papermaking properties of Eucalyptus trees, woods, and pulp fibers. Eucalyptus Online Book & Newsletter.- Chapter 14 (Jul) 2009 110 pgs www.eucalyptus.com.br/eucaliptos/ENG14.pdf

411.

Shapiro, S. – Formation and fiber orientation sensors for web quality optimization. In: Papermakers Conference. TAPPI, Philadelphia: 24-27/03/1996 pg. 17.

427.

Fengel, D. and Wegener, G. – Wood chemistry, ultrastructure, reactions. De Gruyter, Berlin, 1983

429.

Stark, H. – Pulp properties of TCF pulps. In: Emerging Pulping & Bleaching Technologies Workshop. TAPPI, Durhan, 1995 Section Bleaching III.

430.

Stone, J. E. and Scallan, A. M. – A structural model for the cell wall of water swollen sood pulp fibres based on their accessibility to macromolecules. Cellulose Chemistry Technology (2): 343–358 (1968).

432.

Ruel, K.; Billosta, V. C.; Guillemin, F.; Sierra, J. B. and Joseleau, J-P. – The wood cell wall at the ultrastructural scale – formation and topochemical organization. Maderas. Ciencia y tecnología. 8(2):107–116 (2006).

436.

Taher, M. R. B. – Tailored low consistency refining for targeted fiber properties. Master’s Thesis, Abo Akademi, Gadolinia, 2020 50 pgs. www.doria.fi/bitstream/handle/10024/177080/taher_md.pdf?sequence=2&isAllowed=y

437.

Josephson, W.; Jansson, U.; Sezgi, U. S. and Fagerströn, K. – Low consistency refining of a non-conventionally cooked pulp. In: Papermakers Conference. TAPPI, Atlanta, 1999 Book 2 pgs. 729–739.

441.

Salmén, L. – Wood morphology and properties from molecular perspectives. Annals of Forest Science, (72):679–684 (2015).

442.

Park, S. W. and Pinto, J. M. – Cinética da polpação kraft. Parte 1: a evolução de modelos empíricos para modelos mecanísticos. In: XXIII Congresso Anual de Celulose e Papel, ABTCP, São Paulo, 1990 pgs. 69–91.

444.

Sjöström, E. – Wood chemistry – fundamentals and applications, 2nd. Edition. Academic Press, San Diego, 1993 pg. 204–222.

445.

Milichovsky, M. – A new concept of chemistry refining process. Tappi Journal, 62 (10): 221–231 (1990).

446.

Homas, L. H.; Kennedye, C. J.; Mayb, R. P.; Altanerf, C. M.; Apperleyg, D. C.; Wessh, T.J. and Jarvisi, M. C. – Structure of cellulose microfibrils in primary cell walls from collenchyma. Plant Physiology, 161 (1): 465–476 (2013).

447.

Genco, I.; Boufi, S.; Pèlach, M. A.; Alcalà, M.; Vilaseca, F. and Mutjéa, P. – Nanofibrillated cellulose as paper additive in eucalyptus pulps. BioResources, 7 (4): 5167–5180 (2012).

448.

Chinga-Carrasco, G. – Cellulose fibres, nanofibrils and microfibrils: The morphological sequence of MFC components from a plant physiology and fibre technology point of view. Nanoscale Research Letter,. 6 7 pgs. (2011).

449.

Donaldson, L. – Cellulose microfibril aggregates and their size variation with cell wall type. Wood Science and Technology, (41): 443–460 (2007).

450.

Sjösted A. – Preparation and characterization of nanoporous cellulose fibres and their use in new material concepts. Doctoral Thesis. KTH Royal Institute of Technology. Stockholm, 2014 65 pgs. https://www.diva-portal.org/smash/get/diva2:761478/FULLTEXT01.pdf

452.

Smook, G. A. – Preparation of papermaking stock In: Handbook of Pulp and Paper Thechnologists – Chapter 13. Angus Wilde, 2002. pgs 190–204

453.

Abdul Khalil, H. P. S.; Davoudpour, Y.; Nazrul Islama, Md; Mustaphaa, A.; K. Sudeshd, Rudi Dungani, R. and Jawaidb, M. – Production and modification of nanofibrillated cellulose using various mechanical processes: A review. Carbohydrate Polymers 99: 649–665 (2014)

454.

Sjöström, E. – Production of microfibrillated cellulose by LC-refining. Master’s Thesis, Abo Akademi, 2018 77 pgs https://www.doria.fi/handle/10024/165125

456.

Gharehkhani, S.; Sadeghinezhada, E.; Kazi, S. N.; Yarmanda, H.; Badarudina, A.; Safaei, M. R. and Zubir, M. N. M. – Effect of pulp consistency during refining of pulp refining on fiber properties—A review. Carbohydrate Polymers Journal, 115: 785–803 (2015).

458.

Kahilahti, M. – Roundwood chipping for quality pulp. World Pulp and Paper Technology, 1995/1996: 57–58.459.

461.

Gorshkova, T.; Brutch, N.; Chabbert, B.; Deyholos, M.; Hayashi, T.; Lev-Yadun, S.; Mellerowicz, E. J.; Morvan, C.; Neutelings, G. and Pilate, G. – Plant fiber formation: state of the art, recent and expected progress, and open questions. Critical Reviews in Plant Sciences, 31: 201–228 (2012).

462.

Brandberg, A. – Insights in paper and paperboard performance by fiber network micromechanics. KTH Royal Institute of Technology. Stockolm, 2019 20 pgs www.diva-portal.org/smash/get/diva2:1355441/FULLTEXT01

486.

Perissoto, D. O.; Nascimento, E. A. and Morais, S. A. L. – Estudo dos extrativos da polpa kraft de eucalipto. Parte 2: Branqueamento dos extrativos e da polpa kraft. O Papel, 61 (8): 69–72 (2000).

488.

Salmén, N. L. and Olsson, A-M. – Interaction between hemicelluloses, lignin and cellulose: structure-property relationships. Journal of Pulp and Paper Science, 24 (3): 99–103 (1998).

521.

Gonzaga, J. V. – Qualidade da madeira e da celulose kraft de treze espécies de Eucalyptus. Master’s Thesis, Universidade Federal de Viçosa, Viçosa, 1983 119 p.

550.

Zhong, R. and Ye, Z-H. – Secondary cell walls: biosynthesis, patterned deposition and transcriptional regulation. Plant and Cell Physiology, 56 (2): 195–214 (2015).

555.

Dowens, G. M. – Wood properties of interest in plantation productivity. In: Sampling Plantation Eucalyptus for Wood and Fibres Properties. Chapter 1. Ed. Dewens, G. M. et al CSIRO Publishing, Collingwood, 1997 pgs. 1–8.

561.

Panshin, A. J. and Zeeuw, C. de – Textbook of Wood Technology, 4th Edition. McGraw Hill, New York, 1980. 722 pgs.

566.

Mohlin. U. B. – Cellulose fiber bonding. Part 3: The effect of beating and drying on inter fiber bonding. Svensk Papperstiding, 78 (9): 338–341 (1975).

571.

Salmén, L.; Olsson, A-M.; Stevanic, J. S.; Simonović, J. and Radotić, K. – Structural organization of the wood polymers in the wood fibre. BioResources, 7 (1): 521–532 (2012).

572.

Leask, R. A. – Introduction. In: Pulp and Paper Manufacture, Volume 2, Mechanical Pulping. R. A. Leask, Ed. Joint-Textbook Committee, Technical Section. CPPA/TAPPI.

575.

Berggren, R. – Cellulose degradation in pulp fibers studied as changes in molar mass distributions. Doctoral Thesis, Royal Institute of Technology, Stockholm, 2003 94 pgs https://www.diva-portal.org/smash/get/diva2:9304/FULLTEXT01.pdf

576.

Fagerstedt, K. V.; Kukkola, E. M.; Koistinen, V. V. T.; Takahashi, J. and Marjamaa, K. – Cell wall lignin is polymerised by class III secretable plant peroxidases in Norway spruce. Journal of Integrative Plant Biology, 52 (2): 186–194 (2010).

577.

Du, X.; Gellerstedt, G. and Li, J. – Universal fractionation of lignin–carbohydrate complexes (LCCS) from lignocellulosic biomass: An example using spruce wood. Plant Journal, 74 (2): 328–338 (2013).

578.

Youssefian, S. and Rahbar, N. – Molecular origin of strength and stiffness in bamboo fibrils. Scientific Reports, 5: 1–13 (2015).

580.

Tubino, M. and Mambrim filho, O. – Em busca da seletividade no branqueamento com peróxido de hidrogênio: estudos de parâmetros de ativação termodinâmicos e catalíticos. O Papel, 60 (9): 41–44, 48–55 (1999).

581.

He, L.; Terashima, N. – Formation and structure of lignin in monocotyledons. IV Deposition process and structural diversity of the lignin in the cell wall ofsugarcane and rice plant studied by ultraviolet microscopic spectroscopy. Holzforschung, 45: 191–198 (1991).

583.

Meltzer, F. P. and Sepke, P.-W. – New ways to forecast the technological results of refining. In: III International Refining Conference and Exhibition. PIRA/IPST, Atlanta, 1995 Paper 2 26 pgs.

584.

Derakhshandeh, B.; Kerekes, R.; Hatzikiriakos, S. and Bennington, C. – Rheology of pulp fibre suspensions: A critical review. Chemical Engineering Science 66: 3460–3470 (2011).

585.

Stuart, S.-A. and Evans, R. – X-ray diffraction estimation of the microfibril angle variation in eucalypt wood. Appita Journal, 48 (3): 197–200 (1995).

586.

Eichhom, S. J. et al – Review: current international research into cellulosic fibres and composites. Journal of Material Science, 36: 2107–2131 (2001).

587.

Adler, D. – A Study of the molecular mechanics of wood cell walls. Masterthesis, Massachusettes University of Technology, Cambridge, 2013 49 pgs https://dspace.mit.edu/bitstream/handle/1721.1/82339/861698451-MIT.pdf;sequence=2

588.

Eklund, D. and Lindström, T. – Paper chemistry – An introduction. DT Paper Science Publications, Grankulla, Finland, 1991 305 pgs.

589.

Martinez, P. C. and, S. W. – Modelos matemáticos de uma fibra celulósica em processo de refino em baixa consistência. In: V CIADICYP – Congreso Iberoamericano de Investigación en Celulosa y Papel, Guadalajara, 2006 12 pgs https://www.eucalyptus.com.br/artigos/2006_Modelagem+Fibras+Refinador.pdf

590.

Rawat, N. and McDonough, T. J. – Effects of pulping conditions on the bleachability of hardwood kraft pulps: Effects of effective alkali charge in the pulping of birch and maple. In: Pulping Conference. TAPPI, Montreal, 1998.

593.

Chauhan, A.; Kumari, A. and Ghosh, U. K. – Blending impact of softwood pulp with hardwood pulp on different paper properties. Tappsa Journal,. 2: 16–22 (2013).

594.

Hubbe, M. A.; Venditti, R. V. and Rojas, O. J. – What happens to cellulosic fibers during papermaking and recycling? A Review. BioResources, 2 (4): 739–788 (2007).

596.

Eder, M.; Arnould, O.; Dunlop, J. W. C.; Hornatowska. J. and Salmén, L. – Experimental micromechanical characterization of wood cell walls Wood Science and Technology, 47 :163–182 (2013).

599.

Maaß, M-C.; Saleh, S.; Militz, H. and Volkert, C. A. – The structural origins of wood cell wall toughness. Advance Material, 32 6 pgs (2020).

601.

Uesaka, T. and Moss, C. – Effects of fibre morphology on hygroexpansivity of paper: a micromechanics approach. In: 11st Fundamental Research Symposium. PIRA, Leatherhead, 1997 pgs. 663.

603.

Bjurhager, I. – Mechanical behaviour of hardwoods – effects from cellular and cell wall structures. KTH Royal Institute of Technology, Stockolm, 2008 36 pgs. www.diva-portal.org/smash/get/diva2:14173/FULLTEXT01

604.

Cave, I. D. and Hurt, L. – The anisotropic elasticity of the plant cell wall. Wood Science and Technology, 2 (1): 268—278 (1968).

605.

Seth, R. S.; Francis, D. W. and Bennington, C. P. J. – The effect of mechanical treatment during medium stock concentration fluidization on pulp properties. Appita, 46 (1): 55–58, 60 (1993).

610.

Lumiainen, J. – Refining – a key to upgrading the papermaking potential of recycled fibre. Paper Technology,35 (9): 41–44 (1994).

612.

Donaldson, L. – Microfibril angle: measurement, variation and relationships—A review. IAWA Journal, 29 (4): 345–386 (2008).

613.

Somerville, C.; Bauer, S.; Brininstool, G.; Facette, M.; Hamann, T.; Milne, J.; Osborne, E.; Paredez, A.; Persson, S.; Raab, T.; Vorwerk, S e Youngs, H. – Toward a systems approach to understanding plant cell walls. Science, 306: 2206–2211 (2004).

736.

Jansson, J. – The influence of pH on fiber and paper properties: Different pH levels during beating and sheet forming. Master’s Thesis. Karlstad University, Karlstad, 2015 43 pgs www.diva-portal.org/smash/get/diva2:823180/FULLTEXT01

888.

Sharkawya, K. E.; Haavistob, S.; Koskenhely, K. and Paulapuroa, H. – Effect of fiber flocculation and filling design on refiner loadability and refining characteristics. BioResources, 3 (2): 403-424 (2008).

Title: The Fiber Cell Wall
Author: Vail Manfredi
Publisher: Springer Nature Switzerland
Book: Eucalyptus Kraft Pulp Refining
Print ISBN: 978-3-031-47284-8

Electronic ISBN: 978-3-031-47285-5

Copyright Year: 2024
DOI: https://doi.org/10.1007/978-3-031-47285-5_6

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