The claim that the toughest material on Earth only gets stronger under extreme temperatures sounds like something out of a superhero movie, but according to a recent scientific study , it’s totally real.
Keep reading to find out more about this wonder substance that ranks up there with vibranium.
Tough Stuff
The Earth’s toughest material is a metallic alloy consisting of chromium, cobalt, and nickel. It is 100 times stronger than graphene , a supermaterial 200 times stronger than steel and 1,000 times lighter than paper.
While researchers were previously aware that the material was tough, they were surprised to learn it becomes even tougher when exposed to extremely cold temperatures. Other materials, including graphene, get increasingly more brittle as temperatures drop, while this high entropy alloy (HEA) is extremely fracture-resistant.
Robert Ritchie, a University of California Berkeley professor, senior faculty scientist at the Lawrence Berkeley National Laboratory, and study co-author, told Live Science: “The toughness of aluminum alloys used in aircraft is 35 megapascals per meter. This material has a toughness of 450 to 500 megapascals per meter… these are mind-boggling numbers.”
Real-World Uses
So, what applications would be ideal for this tough alloy? It could be incorporated into space infrastructure or used to build fracture-resistant containers for clean energy projects. For example, a good application may be hydrogen storage containers for hydrogen-powered vehicles. The problem is that nickel and cobalt are extremely costly, so the alloy will not be used outside of a laboratory anytime soon, according to Ritchie.
HEAs are comprised of an equal mix of elements, while other alloys are made of one predominant element with other elements mixed in. The chromium-cobalt-nickel alloy bends under pressure, and this malleability keeps it from fracturing. When exposed to a lot of pressure, it doesn’t deform or break like other materials do. In fact, it becomes even stronger in colder temperatures.
cientists initially tested the alloy by exposing it to liquid nitrogen in temperatures around minus 321-degress Fahrenheit. Instead of weakening, the alloy got stronger. Researchers then exposed the alloy to liquid helium, which can reach temperatures of minus 424-degrees Fahrenheit.
Scaling Up
Compared to graphene, the HEA was exponentially tougher. According to physicist Dong Liu, a study co-author from Bristol University, graphene is strong but lacks damage tolerance. “It’s very brittle and shatters just like a mug you throw on the floor that shatters into pieces,” he told Live Science.
And while graphene may be tough, it only maintains its strength in “nanometer-level scales,” while the chromium-cobalt-nickel alloy was tested in cigarette-pack-sized portions. This makes it a more practical material for common items.
Further research on the HEA needs to be conducted to determine its usability in real-world conditions. Ritchie, meanwhile, is keen on developing new alloys that are similarly tough using a variety of different elements from the periodic table, thus creating “millions of new alloys.”