By splitting up wood pulp into cellulose nanofibers and
rearranging the fibers into an entangled porous mesh, researchers have made a
nanopaper that is stronger than cast iron and tougher than bone. The nanopaper
is seven times stronger and two to three times as stretchy as conventional
paper. It could be used to make tough packaging material, filters, membranes,
and even car and aircraft parts. “Wood pulp is widely available, and there is
the potential to produce nanofibers in very large quantities,” says Lars
Berglund, a biocomposites researcher at the Royal Institute of Technology,
in Stockholm, Sweden, and coauthor of a paper in Biomacromolecules that describes the new material.
Paper gets tough: An entangled film of 10-to-40-nanometer-thick cellulose fibers makes strong, tough nanopaper that could be used in medical implants and vehicle parts. A cross section of a fracture surface in the paper shows layers of cellulose fibers.
Cellulose, a stiff chain of glucose units, is one of the
most abundant natural polymers: it makes up 90 percent of cotton and half of
wood. Plant cell walls are made of multiple strands of cellulose bound into
fibers typically 5 to 10 nanometers thick. To make regular paper, wood chips
are heated with chemicals or mechanical force to create pulp. Aggregated, 30-micrometer-thick
bundles of cellulose fibers in the pulp are then intertwined to create sheets.
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The new nanopaper is made of much thinner 10-to-40-nanometer-thick
fibers. Individual cellulose strands are very robust, Berglund says. “They have
properties similar to Kevlar,” he notes. The hydroxyl groups and oxygen
molecules on individual nanofibers attach to each other strongly. Even if a
sudden impact ruptures the bonds between some of the nanofibers, the defect is
small enough that the entire material does not fail. The paper can withstand
nearly two-thirds more force than cast iron before it breaks.
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The stretchiness comes from the pores in the mesh of
nanofibers. When the nanopaper is stretched, there is enough space for the
fibers to slip against each other. “You can stretch it up to 10 percent before
it fails,” Berglund says. “Conventional paper can stretch a maximum of 3 to 4 percent,
then it breaks.”
To make the nanopaper, Berglund and his colleagues first
expose wood pulp to enzymes and mechanical force. This separates the pulp into
cellulose microfibers. The pulp is passed through a device that uses
high-pressure and high velocities in tiny microfluidic channels to create
a uniform suspension of nanofibers in water. Finally, the researchers pass the
suspension through a filter to create a gel, which they compress to make 100-micrometer-thick
sheets.
Berglund says that the dilute, uniform suspension of the
nanofibers is critical. It distributes the fibers homogeneously in the paper,
making it strong. The porosity of the paper is also crucial. The researchers found
that higher porosities led to paper that is stronger–that is, it handles more
load per unit area–and tougher, which means that it does not crack easily.
The Swedish work is part of the broader interest in making
polymers infused with nanomaterials, such as clay nanoparticles, carbon
nanotubes, or graphene, in lieu of using traditional fillers such as glass
fibers and carbon black. Compared with carbon nanotubes, cellulose is low cost and
abundant. “Cellulose is a fantastic filler because it’s a renewable resource,”
says Chris Weder, a
professor of macromolecular science and engineering at Case Western Reserve
University. “I think it’s a fantastic way to tailor properties of material by
way of making nanocomposites.”
Weder says that the researchers will have to test how the nanopaper
holds up when wet. He thinks that the mechanical properties of the material
might degrade in the presence of water. However, he believes that the new work
fills an important knowledge gap. “If you want to understand how nanocomposites
behave mechanically, it is helpful to understand how a material formed by the
nanofibers themselves would behave.”
