New technique helps recycle wood into stronger material than steel

A team at the University of British Columbia has developed a new technique that turns waste wood into a material that is five times stronger than natural wood.

Orlando Rojas, an expert at the University of British Columbia, Canada, and colleagues found a new way to recycle wood into a material that is five times stronger than natural wood and can be made from any wood by-product, including both shavings and sawdust. The new study was published in the journal Nature on May 19.

Picture 1 of New technique helps recycle wood into stronger material than steel

Waste wood can be recycled into new materials with some properties better than natural wood.

Wood is an incredibly versatile material, yet millions of tons end up in landfills each year. To build a truly circular economy, wood needs to be reused on a larger scale.

Rojas' team devised a way to dissolve lignin - the glue-like ingredient inside plant cell walls - and expose cellulose nanofibers - tiny fibers that are also found in plant cell walls. The new method requires a solvent called dimethylacetamide, which is used together with dimethylacetamide.

When two pieces of treated wood are combined, the nanofibers bond to create a recycled material the team calls "healing wood". Although it no longer looks like natural wood, the new material possesses better mechanical properties. Tests show it to be more resistant to fracture than stainless steel or titanium alloys.

"We recorded mechanical strength beyond the starting material. The reason is that we used the inherent properties of cellulose, which holds together very firmly thanks to hydrogen bonding," says Rojas.

The University of British Columbia method helps recycle wood to create new objects. Not only that, the treatment process can also be repeated on the same piece of wood to prolong the life of the wood.

"This is a really sophisticated way to heal wood, using a common cellulose solvent, restoring and enhancing the mechanical properties of natural materials. The method is certainly scalable and The challenge is to take it to the next level," said Steve Eichhorn, an expert at the University of Bristol, UK.

The team has not examined how much the new method would cost if scaled up to an industrial scale. "The processes we use are very typical in the woodworking industry. So scaling won't be an issue," says Rojas.

Update 26 May 2022
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