Nanomechanical subsurface characterisation of cellulosic fibres

TL;DR

This paper presents an atomic force microscopy-based method for detailed, three-dimensional subsurface mechanical characterization of cellulosic fibres, revealing insights into their hierarchical structure and effects of processing.

Contribution

It introduces a novel nanomechanical imaging approach combining AFM and fluorescence microscopy to analyze fibre subsurface properties in detail.

Findings

Identified protective walls within fibre structure against mechanical loading.

Mapped spatially resolved mechanical properties in dry and wet conditions.

Correlated mechanical data with fluorescent labelling of fibre components.

Abstract

The mechanical properties of single fibres are highly important in the paper production process to produce and adjust properties for the favoured fields of application. The description of mechanical properties is usually characterised via linearized assumptions and is not resolved locally or spatially in three dimensions. In tensile tests or nanoindentation experiments on cellulosic fibres, only one mechanical parameter, such as elastic modulus or hardness, is usually obtained. To obtain a more detailed mechanical picture of the fibre, it is crucial to determine mechanical properties in depth. To this end, we discuss an atomic force microscopy-based approach to examine the local stiffness as a function of indentation depth via static force-distance curves. This method has been applied to linter fibres (extracted from a finished paper sheet) as well as to natural raw cotton fibres to better understand the influence of the pulp treatment process in paper production on the mechanical properties. Both types of fibres were characterised in dry and wet conditions with respect to alterations in their mechanical properties. Subsurface imaging revealed which wall in the fibre structure protects the fibre against mechanical loading. Via a combined 3D display, a spatially resolved mechanical map of the fibre interior near the surface can be established. Additionally, we labelled fibres with carbohydrate binding modules tagged with fluorescent proteins to compare the AFM results with fluorescence confocal laser scanning microscopy imaging. Nanomechanical subsurface imaging is thus a tool to better understand the mechanical behaviour of cellulosic fibres, which have a complex, hierarchical structure.