Another major step towards room-temperature superconductivity

Mainz, May 25th, 2019

A hydrogen-rich material becomes superconductive under high pressure and at minus 23 degrees Celsius. The discovery is another important step towards reaching zero electrical resistance at temperatures relevant for energy applications.

Fewer power plants, less greenhouse gases and lower costs: enormous amounts of electricity could be saved if researchers discovered the key to superconductivity at environmental temperatures. Because superconductors are materials that conduct electric energy without losses. A team from the Max Planck Institute for Chemistry (MPIC) in Mainz has come a step closer to this goal. The researchers around Mikhail Eremets synthesized lanthanum hydride, a material that shows zero electrical resistance under high pressure at minus 23 degrees Celsius. So far, the record for high-temperature superconductivity was minus 70 degrees Celsius.

“Our study is a major step and milestone on the road to superconductivity at room temperature”, says Eremets, a research group leader at MPIC. For their experiments, the scientists synthesized small amounts of lanthanum hydride (LaH10).
In a special chamber only a few hundred cubic microns in size, they exposed the samples to a pressure of 1.7 megabar, which is 1.7 million times the atmospheric pressure, and then cooled them. After reaching the critical temperature of minus 23 degrees Celsius (250 K), the electrical resistance of the samples dropped to zero. Since the superconductivity cannot be clearly demonstrated by resistance measurements alone, the researchers additionally performed measurements in an external magnetic field. A magnetic field disturbs the superconductivity, causing the transition to shift to lower temperatures. That is exactly what the physicists observed.

Powerful Pressure: In a less than fist-sized diamond anvil cell, more than one million bars can be created between two conical cut diamonds, with some materials becoming superconducting at relatively high temperatures. Photo: Thomas Hartmann

The latest success builds on major breakthrough that Eremets and colleagues had achieved a few of years ago: they discovered conventional superconductivity in hydrogen sulfide under 2,5 megabar pressure at minus 70 degrees Celsius, which was at much higher temperature than ever observed before. Apparently, hydrogen-rich compounds are capable of superconducting at particularly high temperatures - if they can be brought into a metallic state. In this case the pressure forms the hydride from the metal lanthanum and the hydrogen gas. This is exactly what the high pressure causes. It is also necessary to put the lanthanum hydride under pressure in order for the hydride to form from the metallic lanthanum and hydrogen.

The high pressure produces metallic lanthanum hydride

Until the discovery of high-temperature superconductivity in hydrogen sulfide, copper-containing ceramics held the superconducting records. However, even the best of these materials loses their electrical resistance only at minus 135 degrees Celsius. Additionally, the superconductivity also arises through a different mechanism than with metallic superconductors. Therefore, the ceramic superconductors are called unconventional. The conventional metallic superconductors usually lose their electrical resistance at much lower temperatures. That´s why the discovery of high-temperature superconductivity in metallic hydrogen sulfide attracted much attention among physicists.

With further experiments, the Mainz Max Planck researchers demonstrated that lanthanum hydride is one of the conventional superconductors. They replaced the hydrogen in the lanthanum hydride with the heavier hydrogen isotope deuterium. As predicted by the Bardeen-Cooper-Schrieffer (BCS) theory, the critical temperature of superconductivity in the lanthanum deuteride strongly decreased to minus 93 degrees Celsius (180 K).

However, the team of Mikhail Eremets is not satisfied with the current success. Currently, the scientists are searching for superconductivity in yttrium hydride. “With this material we expect to achieve superconductivity at even higher, ambient temperatures”, says Eremets.