Jul 21, 2017
Researchers Create Soft, Flexible Material That's 5 Times Stronger Than Steel
The old cliché that looks can be deceiving definitely comes to mind when considering a new material developed by researchers from the Hokkaido University.
Soft But Tough
The old cliché that looks can be deceiving definitely comes to mind when considering a new material developed by researchers from the Hokkaido University. It looks soft and squishy — which it is — but it's as tough as metal. In fact, its developers say it's five times stronger than carbon steel, while at the same time having the flexibility of rubber.
The reinforced material is a product of combining hydrogels, typically found in products like contact lenses, with glass fibers. The result is a tough but bendable mesh that's built to maximize resilience. "It's the strongest soft material ever obtained by human beings," lead researcher Jian Ping Gong told CNN.
The new fiber-reinforced composite demonstrates "extremely high toughness and tensile properties, far superior to those of the neat components, indicating a synergistic effect," the team wrote in their research, which was published in the journal Advanced Functional Materials. Based on how much energy is needed to destroy it, this fiber-reinforced hydrogel is about 100 times tougher than regular hydrogels, and 25 times stronger than ordinary glass fiber fabric.
The inspiration for the material, Gong explained, comes from nature. "Sometimes when I see a flower coming out from a very hard floor — concrete crack — I was wondering why the small flower, such a small lovely flower, has such a big large energy to come out," she told CNN. "This gel itself looks very soft and weak but it can create a huge amount of energies."
Flexible Range of Applications
With today's more advanced engineering and design technologies, scientists have been experimenting with a number of materials to come up with so-called metamaterials. These are synthetic composites of existing materials with properties not found in their original components. Research in this field has led to the development of several shape-shifting metamaterials. One can be used for charging devices wirelessly, and another that moves using light.
The Japanese fiber-reinforced hydrogel, on the other hand, offers even more potential applications. "The material has multiple potential applications because of its reliability, durability and flexibility. For example, in addition to fashion and manufacturing uses, it could be used as artificial ligaments and tendons, which are subject to strong load-bearing tensions," Gong said in a press release.
Indeed, such a soft but tough material seems perfect for biological substitutes; artificial joints made with it could be even stronger than the real thing. Gong's team is already in talks for potential collaboration in developing artificial cartilages with several companies.
Apart from developing artificial organs, Gong also sees applications in sports clothing and protective gear, such as helmets and bullet proof vests. "I think it could have very good performance against a bullet," she told CNN. Even better, because the composite hydrogel has a 40 percent water level, it's also environmentally friendly.
Of course, the technology has not yet been perfected, but it has opened the door for similar work. For Gong and her team, the goal seems much simpler. "If our material can … make people live in better ways, I think we will be very, very happy."