Abstract
Strongly interacting solvents are needed to dissolve cellulose; therefore, in the past the interpretation of the uncommon solution behavior of cellulose and its derivatives was based mainly on energetic (enthalpic) considerations, for example, hydrogen bonding. These attempts have not been very successful. The present paper demonstrates that entropic effects influence the solution behavior much stronger than hitherto supposed. In the well-known Flory–Huggins theory the driving force for dissolution of flexible chains is the configurational entropy of mixing. This large entropy is strongly reduced by the chain stiffness of the cellulose backbone and by the strictly regular primary structure of this polysaccharide. It strongly reduces the driving force for dissolution. The entropy of mixing becomes largely increased again by the attachment of long side chains and causes solubility with surprising efficiency (hairy rod principle). This effect is demonstrated with several examples. Among others, the surprising insolubility of short, regular-selectively substituted cellulose chains is explained, although long chains of the same substitution pattern are soluble. The striking behavior of cellulose ethers in water is based on the hydrophobic effect, which causes an increased order of the polymer surrounding water molecules. The induced order results in a very pronounced decrease of entropy of mixing that overcompensates the positive configurational entropy of mixing. Common rules of basic thermodynamics now predict phase separation on heating, contrary to the Flory–Huggins theory, which can only predict phase separation on cooling.
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References
Ballauff M. 1986. Phase equilibria in rod-like systems with flexible chain molecules. Macromolecules 19: 1366-1374.
Bethe H. 1935. Proc. Roy. Soc. (London) A150: 552.
Burchard W. 1965. Ñber die Abweichungen von der idealen Knäuelstatistik bei Amylose-und Cellulose-tricarbanilaten in einem Θ-Lösungsmittel. Makromol. Chem. 88: 11-28.
Burchard W. 1983. Static and dynamic light scattering from branched polymers and biopolymers. Adv. Polym. Sci. 48: 1-124 (see pp. 85-92).
Burchard W. 1985. New aspects of polymer characterization by dynamic light scattering. Chimia 39: 10-18.
Burchard W. 1986. Theory of cyclic macromolecules. In: Semlyen J.A. (ed.) Cyclic Polymers. Elsevier, London and New York, pp. 43-64, Eq. 93.
Burchard W. and Schmidt M. 1979. The diffusion coefficient of branched poly(vinyl-acetate) and poly(vinylacetate) microgels measured by quasi-elastic light scattering. Ber. Bunsenges. Phys. Chem. 83: 388-391.
Burchard W. and Schulz L. 1989. Lösungsstruktur von Cellulose 2. 5-Acetaten. Papier 43: 665-674.
Burchard W., Schmidt M. and Stockmayer W.H. 1980. Information on poly-dispersity and branching from combined quasi-elastic light scattering. Macromolecules 13: 1265-1272.
De Gennes P.-G. 1979. Scaling Concepts in Polymer Physics. Cornell University Press, Ithaca, NY.
Demeter J., Mormann W., Schmidt J. and Burchard W. 2003. Structure in solution of trimethylsilyl cellulose in dependence on the degree of substitution. Macromolecules (submitted).
Einstein A. 1905a. On the movement of small particles suspended in stationary liquids required by the molecular kinetics theory of heat. Ann. Phys. 17: 549-560.
Einstein A. 1905b. Eine neue Bestimmung der Moleküldimensionen. Ph.D. Thesis, ETH Zürich, Switzerland.
Engelskirchen K. 1987. Polysaccharidderivate. In: Bartl H. and Falbe J. (eds) Makromolekulare Stoffe, Houben-Weyl E20: 2047-2136.
Flory P.J. 1942. Thermodynamics of high polymer solutions. J. Chem. Phys. 10: 51-61.
Flory P.J. 1953. Principles of Polymer Chemistry. Cornell University Press, Ithaca, NY.
Flory P.J. 1956a. Statistical thermodynamics of semi-flexible chain molecules. Proc. Roy. Soc. (London) A 234: 60-73.
Flory P.J. 1956b. Phase equilibria in solutions of rod-like particles. Proc. Roy. Soc (London) A 234: 73-88.
Frank H.S. and Evans M.W. 1945. J. Chem. Phys. 13: 507.
Freed K.F. 1987. Renormalization Group Theory of Macromolecules. John Wiley, New York.
Gagnaire D., Saint-Germain J. and Vincedon M. 1983. NMR evidence of hydrogen bonds in cellulose solutions. J. Appl. Polym. Symp. 37: 261-275.
Huggins M.L. 1942. J. Phys. Chem. 46: 151.
Huglin M.B. 1972. Light Scattering from Polymer Solutions. Academic Press, London.
Kamide K. and Saito M. 1984. Effect of total degree of substitution on molecular parameters of cellulose acetate. Eur. Polym. J. 20: 903-914.
Kirkwood J.G. and Riseman J. The intrinsic viscosities and diffusion constants of flexible macromolecules in solution. J. Chem. Phys. 16: 565-573.
Klemm D., Heinze T.J., Philipp B. and Wagenknecht W. 1997. New approach to advanced polymers by selective functionalization. Acta Polym. 48: 277-297.
Klohr E. and Zugenmaier P. 1997. Polymer-solvent interaction of molecular dispersed and supramolecular structures of cellulose urethanes. Macromol. Symp. 120: 219-230.
Kötz J., Bogen I., Heinze U., Heinze T.J. and Klemm D. 1998. Colloidal properties of statistically, block-like and regio-selectively substituted carboxymethyl celluloses. Papier 52: 704-712.
Mann G., Kunze J., Loth F. and Fink H.-P. 1998. Cellulose ethers with a block-like distribution of the substituents by structureselective derivatization of cellulose. Polymer 39: 3155-3165.
Mormann W. and Demeter J. 1999. Silylation of cellulose with hexamethyldisilazane in liquid ammonia. First examples of completely trimethylsilylated cellulose. Macromolecules 32: 1706-1710.
Mormann W. and Demeter J. 2000. Controlled desilation of cellulose with stoichiometric amounts of water in the presence of ammonia. Macromol. Chem. Phys. 201: 163-168.
Nerger D. 1978 Synthese und Eigenschaften von Pol(vinylacetate)-Mikrogelen und ihre Kopplung zu Radial-Blockcopolymeren und Netzwerken. Ph.D. Thesis, University of Freiburg, Germany.
Petzold D., Klemm D., Savin G. and Burchard W. 2003. Investigations on structure of regio-selectively functionalized celluloses in solution, examplified by 3-O-alkyl ethers and using light scattering. Cellulose (to be published).
Potthast A., Rosenau T., Buchner R., Roeder T., Ebner G., Bruglachner H., Sixta H. and Kosma P. 2002. The cellulose solvent N,N-dimethylacetaminide/lithium chloride revisited: The effect of water on physico-chemical properties and chemical stability. Cellulose 9: 41-53.
Rahn K., Heinze T.J., Schmidt J. and Burchard W. 2003. Structure and solubility in THF of cellulose tosylates of various degrees of substitution. Cellulose (manuscript in preparation).
Schmidt M., Nerger D. and Burchard W. 1979. Quasi-elastic light scattering on branched polymers: Part 1. Branched poly(vinylacetates) and poly(vinylacetate) microgels. Polymer 20: 582-588.
Schulz L. and Burchard W. 1993. Lösungsstruktur verschiedener Cellulose Derivate, Polysaccharidforschung, Ergebnisberichte 1987-1993, pp. 9-30.
Schulz L., Seger B. and Burchard W. 2000. Structures of cellulose in solution. Macromol. Chem. Phys. 201: 208-222.
Tanford C. 1973. The Hydrophobic Effect. Wiley, New York.
Wegner G. 1992. Photochemistry and photophysics of nanocomponents prepared from rod-like macromolecules by LB-technique. Mol. Cryst. Liq. Cryst. 216: 7-12.
Wenzel M., Burchard W. and Schätzel K. 1986. Dynamic light scattering from semidilute cellulose tri-carbanilate solutions. Polymer 27: 195-201.
Zugenmaier P. and Derleth Ch. 1998. Phase behavior, structure and properties of regio-selectively substituted cellulose derivatives in the liquid-crystalline state. ACS Symp. Ser. 688: 239-252.
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Burchard, W. Solubility and Solution Structure of Cellulose Derivatives. Cellulose 10, 213–225 (2003). https://doi.org/10.1023/A:1025160620576
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DOI: https://doi.org/10.1023/A:1025160620576