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Materials

"Self-densified" wood could give metal a run for its money

By Ben Coxworth
March 25, 2025
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Although it's already widely used in building construction, traditional wood (pictured) isn't all that it could be
Depositphotos
This diagram illustrates the differences between the self-densified wood (top right) as compared to traditional compressed wood (bottom left)
National Laboratory of Solid State Microstructures & Jiangsu Key Laboratory of Artificial Functional Materials & Department of Materials Science and Engineering, College of Engineering and Applied Sciences, Nanjing University, Nanjing 210093, China, yfchen@nju.edu.cn
Although it's already widely used in building construction, traditional wood (pictured) isn't all that it could be
Depositphotos

While sustainably-grown wood can be an economical and eco-friendly building material, its relatively low tensile strength limits its potential applications. That could soon change, however, thanks to a new self-densifying technique for creating super-strong wood.

Individual wood fibers are made up mainly of cellulose, along with a binder material known as lignin. This mixture forms the wall of what is essentially a long hollow tube – the fiber – which runs lengthwise within the larger piece of wood. The hollow space inside the tube is called the lumen, and it is what limits wood's strength.

A team from China's Nanjing University recently set out to address that shortcoming, by developing the new process.

It begins by boiling a block of wood in a mixture of sodium hydroxide (lye) and sodium sulfite, removing some of the lignin. That block is then immersed in a heated blend of lithium chloride salt and a solvent known as dimethylacetamide. This causes the cellulose (and remaining lignin) to swell, expanding inwards to fill the lumen.

In a final step, the processed wood is left to air-dry at room temperature for 10 hours. As it does so, it uniformly shrinks inwards from all sides, but maintains its original length.

This diagram illustrates the differences between the self-densified wood (top right) as compared to traditional compressed wood (bottom left)
National Laboratory of Solid State Microstructures & Jiangsu Key Laboratory of Artificial Functional Materials & Department of Materials Science and Engineering, College of Engineering and Applied Sciences, Nanjing University, Nanjing 210093, China, yfchen@nju.edu.cn

The resulting material is claimed to exhibit "ultra-high" tensile strength, flexural strength, and impact toughness – much more so than natural wood. It even surpasses wood which has been compressed by traditional methods, in which the fibers are just mechanically flattened in one direction.

And unlike other methods of uniformly densifying wood, it doesn't require an energy-intensive hot-pressing process.

It is hoped that once the technology is developed further, the self-densified wood could be used as an alternative to traditional metals in building construction and other possible applications.

A paper on the research, which was led by Dafang Huang and Jie Li, was recently published in the Journal of Bioresources and Bioproducts.

Source: Journal of Bioresources and Bioproducts via EurekAlert

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MaterialsWoodNanjing UniversityBuilding and Construction
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Ben Coxworth
Based out of Edmonton, Canada, Ben Coxworth has been writing for New Atlas since 2009 and is presently Managing Editor for North America. An experienced freelance writer, he previously obtained an English BA from the University of Saskatchewan, then spent over 20 years working in various markets as a television reporter, producer and news videographer. Ben is particularly interested in scientific innovation, human-powered transportation, and the marine environment.
11 comments
BT
Biodegradability?
Phillip Jenkins
I wonder how straight the wood would be after this treatment, or is the raw timber treated then milled? With this treatment is the timber less prone to pests like termites and can it be safely disposed of?
jimbo92107
Can this process work with balsa wood? Bamboo?
Quentin
Supposedly it is resistant to water damage and thus fungal penetration when treated this way. There are youtubers who tested it as a bullet proof plate alternative.
Alan
What about "ironwood", which is superhard natural wood that typically needs tools developed for metalwork to cut it?
rgbatduke
This process reminds me of one of the hypotheses for how Stradivarius violins got their unique tone. IIRC, they were built with logs that where cut in Scandinavia somewhere and floated down a river to a saltwater fjord or bay, where they sat, in very cold salt water, for some years before being collected, dried out, and eventually milled. The cold saltwater supposedly dissolved the lignin and replaced it with chloride-metal complexes of some sort, and the drying of the swollen logs caused them to compress in a similar manner to become unusually dense, strong, and yet resilient enough to create a unique resonant tone. Special varnishes and skilled construction helped as well.
It sounds like they are basically trying to accelerate this process via chemical means so that it can be turned into assembly line scaled manufactory. I applaud the effort, although I'm wary of the dimethylacetamide. This is an chlorinated organic solvent used to make a variety of products and drugs and isn't by any means the worst thing used for this general purpose, but is also toxic and any sort of chronic exposure or dumping into the environment would be of serious concern. It is known that lye and dimethylacetamide are a "true solvent" for cellulose, which is I'm sure why they are using it here.
It would also be interesting if they sought to REPLACE the cellulose with e.g. something else, e.g. a metal or metal compound, or perhaps calcium carbonate. "Woodcrete", or "ironwood". Resilience from the wood, tensile and compressile strength from the replacement material. Spider silk. I think that's more what was thought to happen with the violin wood.
PAV
I don't know if a house could be livable if it was made up of this material. These are toxic components. Also I believe the material would be a dessicant and absorb moisture right from the air. One more consideration is cost to produce, lithium is an expensive resource and it's only getting costlier.
Aaron MacTurpen
Interesting. It would also be interesting to know if the wood requires special tools to cut, shape, nail, etc. And how toxic the end product is or isn't. And how fire proof/prone it might be. There's a reason pressure-treated lumber isn't normally used in home construction and the chemicals used here aren't much better.
jzj
Given that there are a number of wood buildings that are over 20 stories, and there is a planned 55-story wood building (https://newatlas.com/architecture/mga-timber-tower-milwaukee/), which demonstrate that building with conventional cross-laminated timber is already a known process, why is this new densified wood important?
see3d
@Aaron MacTurpen, Pressure-treated lumber is often used in building houses. I have built 3 homes over a few decades and each had PT lumber used in the construction in areas that might see moisture and could rot. The reason more is not used in construction is the cost. In one of my houses, the entire finished below-ground basement was made from PT lumber and plywood. That was a higher density of PT that you can not even pound a galvanized nail into. They had to use stainless steel nails and a nail gun. The chemicals do not leach out and the drywall and paint keep the chemicals from contact with people and pets.
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