Small Angle Neutron Scattering Shows Nanoscale PMMA Distribution in Transparent Wood Biocomposites.

Sai Venkatesh Pingali,Yoshiharu Nishiyama,Lars A Berglund,Hugh M O’Neill,Yuanyuan Li,Pan Chen,Qiu Zhang

doi:10.1021/acs.nanolett.0c05038

Abstract

Transparent wood biocomposites based on PMMA combine high optical transmittance with excellent mechanical properties. One hypothesis is that despite poor miscibility the polymer is distributed at the nanoscale inside the cell wall. Small-angle neutron scattering (SANS) experiments are performed to test this hypothesis, using biocomposites based on deuterated PMMA and “contrast-matched” PMMA. The wood cell wall nanostructure soaked in heavy water is quantified in terms of the correlation distance d between the center of elementary cellulose fibrils. For wood/deuterated PMMA, this distance d is very similar as for wood/heavy water (correlation peaks at q ≈ 0.1 Å–1). The peak disappears when contrast-matched PMMA is used, indeed proving nanoscale polymer distribution in the cell wall. The specific processing method used for transparent wood explains the nanocomposite nature of the wood cell wall and can serve as a nanotechnology for cell wall impregnation of polymers in large wood biocomposite structures.

Highlights

Transparent wood biocomposites based on poly(methyl methacrylate) (PMMA) combine high optical transmittance with excellent mechanical properties
The use of deuterated MMA (D-MMA) combined with neutron scattering should make it possible to investigate if the present transparent wood is a true polymer matrix nanocomposite in that the polymer is distributed at nanoscale in the wood cell wall “matrix”,20 see Figure 1
Neutron scattering of Native wood (NatW) and delignified wood (DelW) soaked in deuterated water (D2O) give information on the correlation length d, the center-to-center distance between the cellulose fibrils before and after delignification