Scientists from Russia’s Belgorod State University (BelSU) have developed a unique alloy that does not have any analogues when it comes to strength and plasticity at extremely low temperatures. According to the researchers, the material is also cheap and can be widely used in studies of space, world ocean, Arctic, and Antarctic. The results are published in the journal Materials Science and Engineering.
The BelSU scientists managed to synthesize a promising alloy based on iron, cobalt, nickel, and carbon. The alloy preserves its remarkable properties at temperatures up to -150°С and lower.
“Our alloy surpasses all commercial analogs in its characteristics both at room and at cryogenic temperatures. At the temperature of liquid nitrogen, –196°C, it is one and a half times stronger than the best analogue and has an excellent ductility of 24%. Combined with excellent fracture toughness, this provides an optimal balance of mechanical properties,” said BelSU’s senior researcher Dmitry Shaisultanov.
High-strength alloy plastic at liquid nitrogen temperature created in Russia
© Photo : Belgorod State University / BelSU
According to him, carbon, as well as an increased amount of iron, provides additional strength and reduces the cost of the material. The material’s high mechanical properties are the result of the so-called TRIP-effect. The scientists explained that this effect provides a significant increase in strength and plasticity due to altering the crystal structure of the material during cold plastic deformation.
“Such alloys are attractive because of their ability to be deep-drawn, resulting in thin-walled, high-strength hollow parts. Also, they opens up a wide range of opportunities for systems designed for extremely low temperatures - primarily in the development of space and air space, the oceans, the Arctic and Antarctic,” Shaisultanov noted.
The findings improve the understanding of mechanisms that determine the behavior of alloys with TRIP-effect in various conditions. This will allow a more accurate choice of materials and technologies to create products with the desired set of mechanical properties, the scientists explained. The scientific team aims to continue the research in order to adapt the new alloy to 3D-printing industrial technologies.