Mechanical interaction between cellulose microfibril and matrix substance in wood cell wall determined by X-ray diffraction

We investigated mechanical interactions between the cellulose microfibril and the matrix substance in wood cell walls. X-ray diffraction measurements showed that the peak positions of (200) and (004) from cellulose crystals in wood cell walls tended to shift lower and higher toward 2θ, respectively, during water desorption in wood. From our simulations, it is shown that the peak shift of (200) during water desorption is not due to changes in the scattering pattern of the amorphous substance or to lateral expansion of the cellulose crystals due to the Poisson effect in the cellulose microfibril, which is compressed in the molecular chain direction as the amorphous substance shrinks. This suggests that the cellulose microfibril expands transversely during water desorption in the wood cell wall, and that there is a mechanical interaction between the cellulose microfibril and the matrix substance.

[1]  Y. Kojima,et al.  Properties of the cell wall constituents in relation to the longitudinal elasticity of wood , 2003, Wood Science and Technology.

[2]  H. Nishimura,et al.  Fine structure of wood cell walls. I. Structural features of noncrystalline substances in wood cell walls , 1981 .

[3]  N. Barber A Theoretical Model of Shrinking Wood , 1968 .

[4]  Takeshi Okano,et al.  Poisson's ratio of cellulose Iβ and cellulose II , 2004 .

[5]  R. Leicester A rheological model for mechano-sorptive deflections of beams , 1971, Wood Science and Technology.

[6]  R. Leicester,et al.  Mechano-sorptive effects on timber creep , 1997, Wood Science and Technology.

[7]  B. Meylan,et al.  The Anisotropic Shrinkage of Wood. A Theoretical Model , 1964 .

[8]  I. D. Cave A theory of the shrinkage of wood , 1972, Wood Science and Technology.

[9]  I. D. Cave,et al.  Swelling of a fibre reinforced composite in which the matrix is water reactive , 1972, Wood Science and Technology.

[10]  T. Toratti,et al.  Modelling longitudinal elastic an shrinkage properties of wood , 1989, Wood Science and Technology.

[11]  Y. Kojima,et al.  Properties of cell wall constituents in relation to longitudinal elasticity of wood , 2002, Wood Science and Technology.

[12]  J. Gril,et al.  A model of anisotropic swelling and shrinking process of wood , 2001, Wood Science and Technology.

[13]  N. Sobue,et al.  X-ray measurement of lattice strain of cellulose crystals during the shrinkage of wood in the longitudinal direction , 1992 .

[14]  R. E. Mark Cell Wall Mechanics of Tracheids , 1967 .