Li and his team also demonstrated that their material can be used to produce wooden nails as sharp as conventional steel nails.
Unlike steel nails, the wooden nails the team developed are resistant to rusting.
The researchers showed that these wooden nails could be used to hammer together three boards without any damage to the nail.
In addition to knives and nails, Li hoped that, in the future, the material can also be used to make hardwood flooring that was more resistant to scratching and wear.
While Li's method to produce hardened wood is new, wood processing in general has been around for centuries.
However, when wood is prepared for furniture or building materials, it is only processed with steam and compression, and the material rebounds somewhat after shaping.
"When you look around at the hard materials you use in your daily life, you see many of them are man-made materials because natural materials won't necessarily satisfy what we need," Li said.
"Cellulose, the main component of wood, has a higher ratio of strength to density than most engineered materials, like ceramics, metals, and polymers, but our existing usage of wood barely touches its full potential."
Even though it's often used in building, wood's strength falls short of that of cellulose.
This is because wood is made up of only 40–50 per cent cellulose, with the rest consisting of hemicellulose and lignin, which acts as a binder.
Li and his team sought to process wood in such a way as to remove the weaker components while not destroying the cellulose skeleton.
"It's a two-step process. In the first step, we partially delignify wood. Typically, wood is very rigid, but after removal of the lignin, it becomes soft, flexible, and somewhat squishy. In the second step, we do a hot press by applying pressure and heat to the chemically processed wood to densify and remove the water."
After the material is processed and carved into the desired shape, it is coated in mineral oil to extend its lifetime.
Cellulose tends to absorb water, so this coating preserves the knife's sharpness during use and when it is washed in the sink or dishwasher.
Using high-resolution microscopy, Li and his team examined the microstructure of the hardened wood to determine the origin of its strength.
"The strength of a piece of material is very sensitive to the size and density of defects, like voids, channels, or pits.
"The two-step process we are using to process the natural wood significantly reduces or removes the defects in natural wood, so those channels to transport water or other nutrients in the tree are almost gone."
This wood-hardening process has the potential to be more energy-efficient and have a lower environmental impact than for the manufacture of other man-made materials, although more in-depth analysis is necessary to say for sure.
The first step requires boiling the wood at 100° Celsius in a bath of chemicals, which could potentially be reused from batch to batch.
For comparison, the process used to make ceramics requires heating materials up to a few thousand degrees Celsius.
"In our kitchen, we have many wood pieces that we use for a very long time, like a cutting board, chopsticks, or a rolling pin," Li said.
"These knives, too, can be used many times if you resurface them, sharpen them, and perform the same regular upkeep."