It has long been thought that hydrogen could be compressed into a metallic form, where it could conduct electricity and possibly act as a superconductor. What's more, it may remain "metastable" as a solid, even when cooled to room temperatures and pressures. If so, it could act as a superconductor without being chilled or compressed, resulting in cheap energy and new types of transportation.
Hydrogen can be cryogenically frozen into a liquid, and by ramping up the pressure, transformed into a non-metallic, non-conductive solid. In 1935, Princeton physicists Eugene Wigner and Hillard Bell Huntington predicted that with enough pressure, solid hydrogen would become metal and conduct current. However, at higher pressures, hydrogen is forced into defects on a diamond's surface, causing it to crack. What's more, lasers used to measure the pressure and confirm the presence of a metal can cause excessive heating, further stressing the diamonds.Ranga Dias and Isaac F. Silvera
To overcome those issues, the Harvard team fitted their diamond anvil into a cryostat cooled to just above absolute zero. They also perfect a new diamond-polishing technique that would eliminate surface irregularities. That enabled them to crank the vice up to 495 billion pascals (71 million PSI), the highest pressure achieved so far. By shining a low-powered laser that wouldn't harm the diamonds, they detected a change in the hydrogen's reflectance. "Then suddenly, it becomes a lustry, reflective sample, which you can only believe is a metal," Silvera says.
However, other researchers are not convinced that the Harvard team saw hydrogen metal. Rather, they think that the team may have misjudged the pressure, and that the shiny material glimpsed could be alumina residue from the anvil's diamonds. "I don't think the paper is convincing at all," French physicist Paul Loubeyre told Nature. "If they want to be convincing, they have to redo the measurement, really measuring the evolution of pressure."
However, Silvera's team only had one cryostat available, and wanted to avoid doing more tests for fear of breaking their specimen. "Now that that paper has been accepted, we're going to do further experiments," he said. Despite the skepticism, the team is confident of the findings. "It's a tremendous achievement, and even if it only exists in this diamond anvil cell at high pressure, it's a very fundamental and transformative discovery," Silvera said. Pending further testing, you might want to temper your own excitement, however.