What holds paper together: Nanometre scale exploration of bonding between paper fibres

Franz Schmied; Christian Teichert; Lisbeth Kappel; Ulrich Hirn; Wolfgang Bauer; Robert Schennach

doi:10.1038/srep02432

What holds paper together: Nanometre scale exploration of bonding between paper fibres

Franz Schmied, Christian Teichert^*, Lisbeth Kappel, Ulrich Hirn, Wolfgang Bauer, Robert Schennach

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Paper, a man-made material that has been used for hundreds of years, is a network of natural cellulosic fibres. To a large extent, it is the strength of bonding between these individual fibres that controls the strength of paper. Using atomic force microscopy, we explore here the mechanical properties of individual fibre-fibre bonds on the nanometre scale. A single fibre-fibre bond is loaded with a calibrated cantilever statically and dynamically until the bond breaks. Besides the calculation of the total energy input, time dependent processes such as creep and relaxation are studied. Through the nanometre scale investigation of the formerly bonded area, we show that fibrils or fibril bundles play a crucial role in fibre-fibre bonding because they act as bridging elements. With this knowledge, new fabrication routes can be deduced to increase the strength of an ancient product that is in fact an overlooked high-tech material.

Original language	English
Article number	2432
Number of pages	6
Journal	Scientific Reports
Volume	3
DOIs	https://doi.org/10.1038/srep02432
Publication status	Published - 2013

Fields of Expertise

Advanced Materials Science

Treatment code (Nähere Zuordnung)

Basic - Fundamental (Grundlagenforschung)

Access to Document

10.1038/srep02432Licence: CC BY 4.0

CD-Laboratory for Surface Chemical and Physical Fundamentals Of Paper Strength
Hirn, U., Bauer, W., Suppan, L., Miletzky, F. A., Diebald, S., Fischer, W. J., Gilli, E., Schennach, E., Lahti, J. A., Weber, F. & Schennach, R.
1/03/07 → 28/02/14
Project: Research project

Cite this

@article{2f133afb1b63491c89575a80e60484f0,

title = "What holds paper together: Nanometre scale exploration of bonding between paper fibres",

abstract = "Paper, a man-made material that has been used for hundreds of years, is a network of natural cellulosic fibres. To a large extent, it is the strength of bonding between these individual fibres that controls the strength of paper. Using atomic force microscopy, we explore here the mechanical properties of individual fibre-fibre bonds on the nanometre scale. A single fibre-fibre bond is loaded with a calibrated cantilever statically and dynamically until the bond breaks. Besides the calculation of the total energy input, time dependent processes such as creep and relaxation are studied. Through the nanometre scale investigation of the formerly bonded area, we show that fibrils or fibril bundles play a crucial role in fibre-fibre bonding because they act as bridging elements. With this knowledge, new fabrication routes can be deduced to increase the strength of an ancient product that is in fact an overlooked high-tech material.",

author = "Franz Schmied and Christian Teichert and Lisbeth Kappel and Ulrich Hirn and Wolfgang Bauer and Robert Schennach",

year = "2013",

doi = "10.1038/srep02432",

language = "English",

volume = "3",

journal = "Scientific Reports",

publisher = "Nature Publishing Group",

}

TY - JOUR

T1 - What holds paper together: Nanometre scale exploration of bonding between paper fibres

AU - Schmied, Franz

AU - Teichert, Christian

AU - Kappel, Lisbeth

AU - Hirn, Ulrich

AU - Bauer, Wolfgang

AU - Schennach, Robert

PY - 2013

Y1 - 2013

N2 - Paper, a man-made material that has been used for hundreds of years, is a network of natural cellulosic fibres. To a large extent, it is the strength of bonding between these individual fibres that controls the strength of paper. Using atomic force microscopy, we explore here the mechanical properties of individual fibre-fibre bonds on the nanometre scale. A single fibre-fibre bond is loaded with a calibrated cantilever statically and dynamically until the bond breaks. Besides the calculation of the total energy input, time dependent processes such as creep and relaxation are studied. Through the nanometre scale investigation of the formerly bonded area, we show that fibrils or fibril bundles play a crucial role in fibre-fibre bonding because they act as bridging elements. With this knowledge, new fabrication routes can be deduced to increase the strength of an ancient product that is in fact an overlooked high-tech material.

AB - Paper, a man-made material that has been used for hundreds of years, is a network of natural cellulosic fibres. To a large extent, it is the strength of bonding between these individual fibres that controls the strength of paper. Using atomic force microscopy, we explore here the mechanical properties of individual fibre-fibre bonds on the nanometre scale. A single fibre-fibre bond is loaded with a calibrated cantilever statically and dynamically until the bond breaks. Besides the calculation of the total energy input, time dependent processes such as creep and relaxation are studied. Through the nanometre scale investigation of the formerly bonded area, we show that fibrils or fibril bundles play a crucial role in fibre-fibre bonding because they act as bridging elements. With this knowledge, new fabrication routes can be deduced to increase the strength of an ancient product that is in fact an overlooked high-tech material.

U2 - 10.1038/srep02432

DO - 10.1038/srep02432

M3 - Article

VL - 3

JO - Scientific Reports

JF - Scientific Reports

M1 - 2432

ER -

What holds paper together: Nanometre scale exploration of bonding between paper fibres

Abstract

Fields of Expertise

Treatment code (Nähere Zuordnung)

Access to Document

Fingerprint

Projects

CD-Laboratory for Surface Chemical and Physical Fundamentals Of Paper Strength

Cite this