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Abstract

All-cellulose nanocomposite films with different ratios of cellulose I and II were produced by partial dissolution of microfibrillated cellulose using ionic liquid and subsequent film casting. The films were isotropic, transparent to visible light, highly crystalline, and contained different amounts of undissolved cellulose I crystallites in a matrix of dissolved cellulose. X-ray diffraction confirmed that cellulose I, i.e., the major polymorphic modification of cellulose in these nanocomposites, is rearranged to cellulose II crystal packing after the partial dissolution. The all-cellulose nanocomposite showed enhanced thermal properties, with thermal degradation temperature increased by 22% compared with thedissolved cellulose. The SEM and AFM studies verified that the nano-sized cellulose crystallites were well dispersed in the matrix. Results from DMA showed that the storage modulus was increased from 270 MPa for the dissolved cellulose to 1104 MPa for the nanocomposite with lower dissolution grade. This indicates that the all-cellulose nanocomposite films contained undissolved cellulose fragments – possibly cellulose I crystallites or aggregates of crystallites in a matrix of regenerated cellulose.

Keywords

nanocomposite all-cellulose nanocrystals ionic liquid

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References

Schurz

. Trends in polymer science – a bright future for cellulose. Prog Polym Sci 1999; 24(4): 481–483.

Jarvis

. Cellulose stacks up. Nature 2003; 426: 611–612.

Klemm

Heublein

Fink

Bohn

. Cellulose: Fascinating biopolymers and sustainable raw material. Angewandte Chemie (International ed. in English) 2005; 44: 3358–3393.

Nishio

Gilbert

. Hyperfine composites of cellulose with synthetic polymers. Cellulosic polymers blends and compositesChap. 5

Munich

Carl Hanser.

Terbojevich

Cosani

Conio

Ciferri

Bianchi

. Mesophase formation and chain rigidity in cellulose and derivatives. 3. Aggregation of cellulose in N,N-dimethylacetamide lithium-chloride. Macromolecules 1985; 18: 640–646.

Rogers

Seddon

. Ionic liquids: Industrial applications for green chemistry. ACS Symposium Series 818Washington, DCAmerican Chemical Society.

Wasserscheid

Welton

. Ionic liquids in synthesisWeinheimWiley-VCH.

Ward

Hine

. The science and technology of hot compaction. Polymer 2004; 45: 1413–1427.

Cabrera

Alcock

Loos

Peijs

. Processing of all-polypropylene composites for ultimate recycles ability. Proc Inst Mech Eng Part L: J Mater Des Appl 2004; 218: 145–155.

10.

Nishino

Matsuda

Hirao

. All-cellulose composite. Macromolecules 2004; 37: 7683–7687.

11.

Qin

Soykeabkaew

Xiuyuan

Peijs

. The effect of fibre volume fraction and mercerization on the properties of all-cellulose composites. Carbohydr Polym 2008; 71: 458–467.

12.

Gindl

Keckes

. All-cellulose nanocomposite. Polymer 2005; 46(23): 10221–10225.

13.

Nishino

Arimoto

. All-cellulose composite prepared by selective dissolving of fibre surface. Biomacromolecules 2007; 8(9): 2712–2716.

14.

Soykeabkaew

Arimoto

Nishino

Peijs

. All-cellulose composites by surface selective dissolution of aligned ligno-cellulosic fibres. Compos Sci Technol 2008; 68(10–11): 2201–2207.

15.

Duchemin

Newman

Staiger

. Structure–property relationship of all-cellulose composites. Compos Sci Technol 2009; 69: 1225–1230.

16.

Mazza

Catana

D-A

Vaca-Garcia

Cecutti

. Influence of water on the dissolution of cellulose in selected ionic liquids. Cellulose 2009; 16(2): 207–215.

17.

Duchemin

Mathew

Oksman

. All-cellulose composites by partial dissolution in the ionic liquid 1-butyl-3-methylimidazolium chloride. Composites Part A 2009; 40: 2031–2037.

18.

Sugiyama

Vuong

Chanzy

. Electron diffraction study on the two crystalline phases occurring in native cellulose from an algal cell wall. Macromolecules 1991; 24(14): 4168–4175.

19.

Segal

Creely

Martin

Jr Conrad

. An empirical method for estimating the degree of crystallinity of native cellulose using the X-ray diffractometer. Text Res J 1959; 29(10): 786–794.

20.

Murdock

. The form of the X-ray diffraction bands for regular crystals of colloidal size. Phys Rev 1930; 35: 8–23.

21.

Wada

Sugiyama

Okano

. Native celluloses on the basis of 2 crystalline phase (I-alpha/I-beta) system. JAppl Polym Sci 1993; 49: 1491–1496.

22.

Fink

Fanter

Philipp

. Wide angle X-ray investigation on the super molecular structure at the cellulose-I cellulose-II phase-transition. Acta Polym 1985; 36: 1–8.

23.

Han

Yan

. Preparation of all-cellulose composite by selective dissolving of cellulose surface in PEG/NaOH aqueous solution. Carbohydr Polym 2010; 79(3): 614–619.

24.

Yano

Sugiyama

Nakagaito

Nogi

Matsuura

Hikita

. Optically transparent composites reinforced with networks of bacterial nanofibers. Adv Mater 2005; 17: 153–155.

25.

Schadler

Ajayan

Schadler

Braun

. Polymer-based and polymer-filled nanocomposites. Nanocomposite Science and TechnologyWeinheim, p. 77Wiley-VCH Verlag.

26.

Petersson

Mathew

Oksman

. Dispersion and properties of cellulose nanowhiskers and layered silicates in cellulose acetate butyrate nanocomposites. J Appl Polym Sci 2007; 112(4): 2001–2009.

Self-reinforced nanocomposite by partial dissolution of cellulose microfibrils in ionic liquid

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