Cellulose Nanocrystals from Forest Residues as Reinforcing Agents for Composites: A Study from Macro- to Nano-Dimensions

Carbohydrate Polymers

Volumn 139, Issue , 2016, Pages 139-149

  Moriana, Rosana ^a   Vilaplana, Francisco ^b,c   Ek, Monica ^a  

^a ROYAL INSTITUTE OF TECHNOLOGY   (Sweden)

^b ALBANOVA UNIVERSITY CENTER   (Sweden)

^c School of Chemical Science and Engineering   (Sweden)

Author keywords

Cellulose nanocrystals; Forest residues; Physico chemical properties; Reinforcing agents in composites; Thermal properties

Indexed keywords

ASPECT RATIO; BLEACHING; CELLULOSE; CHEMICAL PROPERTIES; CLEANING; FORESTRY; LOGGING (FORESTRY); NANOCRYSTALS; REINFORCEMENT; THERMODYNAMIC PROPERTIES; THERMODYNAMIC STABILITY;

AMORPHOUS COMPONENT; CELLULOSE NANO-CRYSTALS; CELLULOSE NANOCRYSTAL (CNCS); CELLULOSIC FIBERS; CRYSTALLINITY INDEX; FOREST RESIDUE; PHYSICOCHEMICAL PROPERTY; REINFORCING AGENT;

CELLULOSE DERIVATIVES;

CELLULOSE; CHEMICAL PROPERTIES; FORESTS; THERMAL PROPERTIES;

EID: 84952342690     PISSN: 01448617     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.carbpol.2015.12.020     Document Type: Article

References (67)

1. H.P.S. Abdul Khalil, A.H. Bhat, and A.F. Yusra Ireana Green composites from sustainable cellulosic fibres: A review Carbohydrate Polymers 87 2012 963 969
2. M. Ahtee, T. Hattula, J. Mangs, and T. Paakkari X-ray diffraction method for determination of crystallinity of wood pulp Paperi Ja Puu 85 1983 475 480
3. A. Alemdar, and M. Sain Isolation and characterization of nanofibers from agricultural residues - wheat straw and soy hulls Bioresources Technology 99 2008 1664 1671
4. M.J. Antal, G. Várhegyi, and E. Jakab Cellulose pyrolysis kinetics: Revisited Industrial & Engineering Chemistry Research 37 1998 1267 1275
5. J. Araki, M. Wada, S. Kuga, and T. Okano Flow properties of microcrystalline cellulose suspension prepared by acid treatment of native cellulose Colloids Surface A: Physicochemical and Engineering Aspects 142 1998 75 82
6. Association, American Forest and Paper Nanotechnology for the Forest Products Industry. Vision and Technology Roadmap. 2005 TAPPI Press Atlanta
7. H.M.C. Azeredo, L.H.C. Mattoso, D. Wood, T.G. Williams, R.J. Avena-Bustillos, and T.H. McHugh Nanocomposite edible films from mango puree reinforced with cellulose nanofibers J. Food Sci. 74 2009 N31 N35
8. S. Beck-Candanedo, M. Roman, and D. Gray Effect of conditions on the properties behavior of wood cellulose nanocrystals suspensions Biomacromolecules 6 2005 1048 1054
9. A. Bendahou, Y. Habibi, H. Kaddami, and A. Dufresne Physico-Chemical Characterization of Palm from Phoenix Dactylifera-L, Preparation of Cellulose Whiskers and Natural Rubber-Based Nanocomposites Journal of Biobased Materials and Bioenergy 3 2009 1 10
10. M.C. Bibin, A.L. Leão, F.S. Sivoney, S. Thomas, L.A. Pothan, and M. Kottaisamy Isolation of nanocellulose from pineapple leaf fibers by steam explosion Carbohydrate Polymers 81 2010 720 725
11. D. Bondeson, A. Mathew, and K. Oksman Optimization of the isolation of nanocrystals from microcrystalline cellulose by acid hydrolysis Cellulose 13 2006 171 180
12. Y. Chen, C. Liu, P.R. Chang, X. Cao, and D.P. Anderson Bionanocomposites based on pea starch and cellulose nanowhikers hydrolyzed from pea hull fibre: Effect of hydrolysis time Carbohydrate Polymers 76 2009 607 615
13. W. Chen, H. Yu, Y. Liu, P. Chen, M. Zhang, and Y. Hai Individualization of cellulose nanofibers from wood using high-intensity ultrasonication combined with chemical pretreatments Carbohydrate Polymers 83 2011 1804 1811
14. I. Ciucanu, and F. Kerek A simple and rapid method for permethylation of carbohydrate polymers Carbohydrate Research 131 1984 209 217
15. T.C. Davidson, R.H. Newman, and M.J. Ryan Variations in the fibre repeat between samples of cellulose I from different sources Carbohydrate Residues 339 2004 2889 2893
16. X.M. Dong, J.F. Revol, and D.G. Gray Effect of microcrystallite preparation conditions on the formation of collodi crystals of cellulose Cellulose 5 1998 19 32
17. A. Dufresne Interfacial phenomena in nanocomposites based on polysaccharide nanocrystals Composites Interfaces 10 2003 369 387
18. A. Dufresne Nanocellulose. From nature to high performance tailored materials. 2012 De Gruyter Berlin
19. V. Favier, H. Chanzy, and J.Y. Cavaillé Polymer nanocomposites reinforced by cellulose whiskers Macromolecules 28 18 1995 6365 6367
20. F. Fhama, S. Iwamoto, N. Hori, T. Iwata, and A. Takemura Isolation, preparation and characterization of nanofibers from oil palm empty-fruit-bunch (OPEFB) Cellulose 17 2010 977 985
21. T. Hannuksela, M. Tenkanen, and B. Holmborn Sorption of dissolved galactoglucomannans to bleached kraft pulp Cellulose 9 2002 251 261
22. J. He, Y. Tang, and S.Y. Wang Differences in morphological characteristics ofbamboo fibres and other natural cellulose fibres: studies on X-ray diffraction,solid state 13C-CP/MAS NMR, and second derivative FTIR spectroscopy data Iranian Polymer Journal 16 12 2007 807 818
23. M.A. Hubbe, J.R. Orlando, L.A. Lucia, and M. Sain Cellulosic nanocomposites: a review Bioresources 3 2008 929 980
24. T. Iwata, L. Indrarti, and J.-I. Azuma Affinity of hemicellulose for cellulose produced by Acetobacter xylinum Cellulose 5 1998 215 228
25. S. Kalia, A. Dufresne, B.M. Cherian, B.S. Kaith, L. Averous, J. Njuguna, and E. Nassiopoulos Cellulose-based bio- and nanocomposites: A review International Journal Polymer Science 2011 2011 1 35
26. H. Kargarzadeh, I. Ahmad, I. Abdullah, A. Dufresne, S.Y. Zainuding, and R.M. Sheltami Effects of hydcrolysis conditions on the morphology, cristallinity, and thermal stability of cellulose nanocrystals extracted from kenaf bast fibres Cellulose 19 2012 855 866
27. D.Y. Kim, Y. Nishiyama, M. Wada, and S. Kuga High-yield carbonization ofcellulose by sulfuric acid impregnation Cellulose 8 1 2001 29 33
28. T. Kondo Nano-pulverization of native cellulose fibers by counter collision water Cellulose communications 12 2005 189 192
29. M. Le Normand, R. Moriana, and M. Ek Isolation and characterization of cellulose nanocrystals from spruce bark in a biorefinery perspective Carbohydrate Polymers 111 2014 979 987 2014
30. M. Le Normand, R. Moriana, and M. Ek The bark biorefinery: a side-stream from the forest industry converted into nanocomposites with high oxygen barrier Cellulose 21 2014 4583 4594
31. R. Li, J. Fei, Y. Cai, Y. Li, J. Feng, and J. Yao Cellulose whiskers extracted from mulberry: A novel biomass production, carbohydrate polymers Carbohydrate Polymers 76 2009 94 99
32. P. Lu, and Y.L. Hsieh Preparation and properties of cellulose nanocrystals: rods, spheres, and network Carbohydrate Polymers 82 2010 329 336 2010
33. N.E. Marcovich, M.L. Auad, N.E. Bellesi, S.R. Nutt, and M.I. Aranguren Cellulose micro/nanocrystals reinforced polyurethane Journal of Material Research 21 2006 870 881
34. R. Moriana, F. Vilaplana, K. Sigbritt, and A. Ribes-Greus Improved thermo-mechanical properties by the addition of natural fibres in starch-based sustainable biocomposites Composites: Part A 42 2011 30 40
35. R. Moriana, F. Vilaplana, S. Karlsson, and A. Ribes Correlation of chemical, structural and thermal properties of natural fibres for their sustainable exploitation Carbohydrate Polymers 112 2014 422 431
36. R. Moriana, Y. Zhang, P. Mischnick, J. Li, and M. Ek Thermal degradation behaviour and kinetic analysis of spruce glucomannan: a comparative study with the methylated derivatives Carbohydrate Polymers 106 2014 60 70
37. R. Moriana, F. Vilaplana, and M. Ek Forest Residues as Renewable Resources for Bio-Based Polymeric Materials and Bioenergy: Chemical Composition Structure and Thermal Properties. Cellulose 22 2015 3409 3423
38. H.M. Ng, L.T. Sin, T.T. Tee, S.T. Bee, D. Hui, C.Y. Low, and A.R. Rahmat Extraction of cellulose nanocrystals from plant sources for application as reinforcing agent in polymers Composites Part B 75 2015 176 200
39. NREL: Determination of Extractives in Biomass. Laboratory Analytical Procedure. 2005 NREL Golden, CO
40. P. Oinonen, H. Krawczyk, M. Ek, G. Henriksson, and R. Moriana Bioinspired composites from cross-linked galactoglucomannan and microfibrillated cellulose: Thermal, mechanical and oxygen barrier properties Carbohydrate Polymers 136 2016 146 153
41. A. O'Sullivan Cellulose: the structure slowly unravels Cellulose 4 1997 173 207
42. J.K. Pandey, J.-W.L. Won-Shik Chu, and a S.-H. A. Chung-Soo Kim Cellulose Nano Whiskers from Grass of Korea Macromolecular Research 16 2008 396 398
43. Y. Peng, D.J. Gardner, Y. Han, A. Kiziltas, Z. Cai, and M.A. Tshabalala Influence of drying method on the materials propertis of nanocellulose I: thermostability and crystallinity Cellulose 20 2013 2379 2392
44. F.A. Pettolino, C. Walsh, G.B. Fincher, and A. Bacic Determining the polysaccharide composition of plant cell walls Nature Protocols 7 9 2012 1590 1607
45. M.C. Popescu, C.M. Popescu, G. Lisa, and Y. Sakata Evaluation of morphological and chemical aspects of different wood species by spectroscopy and thermal methods Journal of Molecular Structure 988 2011 65 72
46. L.M. Proniewicz, C. Paluszkiewciz, A. Weselucha-Birczysimnska, H. Majcherczyk, S.A. Bara, and A. Konieczna Journal of Molecular Structure 596 2001 163
47. T. Pullawan, A.N. Wilkinson, and S.J. Eichhorn Discrimination of matrix-fibre interactions in all-cellulose nanocomposites Composites Science and Technology 70 2010 2325 2330
48. B.G. Rånby Fibrous macromolecular systems. Cellulose and muscle. The colloidal prperties of cellulose micelles Discussion of the Faraday Society 11 1951 158 164
49. J.F. Revol, L. Godbout, and D.G. Gray Solid self-assembled films of cellulosewith chiral nematic order and optically variable properties Journal of Pulp andPaper Science 24 5 1998 146 149
50. M. Roman, and W.T. Winter Effect of sulfate groups from sulfuric acidhydrolysis on the thermal degradation behavior of bacterial cellulose Biomacro-molecules 5 5 2004 1671 1677
51. M.F. Rosa, E.S. Medeiros, J.A. Malmonge, K.S. Gregorski, D.F. Wood, L.H.C. Mattoso, G. Glenn, W.J. Orts, and S.H. Imam Cellulose nanowhisker from coconut husk fibers: effect of preparation conditions on their theramal and morphological behaviour Carbohydrate Polymers 81 2010 83 92
52. J.F. Saeman, W.E. Moore, R.L. Mitchell, and M.A. Millet Techniques for the determination of pulp constituents by quantitative paper chromatography Tappi journal 37 8 1954 336 343
53. L. Segal, J.J. Creely, A.E. Martin, and C.M. Conrad An empirical methodfor estimating the degree of crystallinity of native cellulose using the X-raydiffractometer Textile Research Journal 29 10 1959 786 794
54. A.N. Shebani, A.J. Van Reenen, and M. Meincken The effect of wood extractives on the thermal stability of different wood species Thermochimica Acta 471 2008 43 50
55. H.A. Silvério, W.P. Flauzino Neto, N.O. Dantas, and D. Pasquini Extraction and characterization of cellulose nanocrystals from corncob for applicationas reinforcing agent in nanocomposites Industrial Crops and Products 44 0 2013 427 436
56. G. Siqueira, J. Bras, and A. Dufresne Cellulose Whiskers versus Microfibrils: Influence of the Nature of the Nanoparticle and its Surface Functionalization on the Thermal and Mechanical Properties of Nanocomposites Biomacromolecules 10 2009 425 432
57. G. Siqueira, H. Abdillahi, J. Bras, and A. Dufresne High reinforcing capability cellulose nanocrystals extracted from Syngonanthus nitens (Capim Dourado) Cellulose 17 2 2010 289 298
58. G. Siqueira, J. Bras, and A. Dufresne Cellulosic Bionanocomposites: A Review of Preparation, Properties and Applications Polymers 2 2010 728 765
59. K.L. Spence, R.A. Venditti, O.J. Rojas, Y. Habibi, and J.J. Pawlak A comparative study of energy consumption and physical properties of microfibrillated cellulose produced by different processing methods Cellulose 18 2011 1097 1111
60. TAPPI. Acid insoluble lignin in wood and pulp T 222 om-06 2006 US TechnicalAssociation of Pulp and Paper Industry
61. TAPPI. Roadmap for the Development of International Standards for Nanocellulose 2011 US TechnicalAssociation of Pulp and Paper Industry
62. TAPPI. Ash in wood, pulp, paper and paperboard: combustion at 525 °C T211om-02 2012 US Technical Association of Pulp and Paper Industry
63. A.F. Turbak, F.W. Snyder, and K.R. Sandberg Micrifibrillated cellulose, a new cellulose product: properties, uses and commercial potential Journal of Applied Polymer Science:Applied polymer Symposium 37 1983 815 827
64. T.H.J.P. Wegner Advancing cellulosed-based nanothecnology Cellulose 13 2011 115 118
65. S. Willför, A. Sundberg, J. Hemming, and B. Holmbom Polysaccharides in some industrially important softwood species Wood Science and Technology 39 4 2005 245 257
66. P.J. Wright, and A.F.A. Wallis Rapid Determination of Carbohydrates in Hardwoods Holzforschung 50 1956 518 524
67. H.Y. Yu, Z.Y. Qin, L. Liu, X.G. Yang, Y. Zhou, and J.M. Yao Comparison of the reinforcing effects for cellulose nanocrystals obtained by sulfuric and hydrochloric acid hydrolysis on the mechanical and thermal properties of bacterial polyester Composites Science and Technology 87 2013 22 28