Room-temperature superconductor claims tease investors, test
In the previous week, a pair of remarkable assertions surfaced from South Korean researchers, triggering a wave of excitement on social media and influencing the stock prices of select companies in China and South Korea.
The claims pertained to the breakthrough identification of a viable superconductor.
Superconductors are substances through which electrical current can flow without any resistance, a characteristic that could revolutionize various domains.
This includes the enhancement of power grids by minimizing energy loss during transmission, as well as the advancement of fields like computing chips, where electrical resistance currently imposes a speed limit.
These assertions emerged in the form of papers published on a platform utilised by scientists to exchange research findings prior to formal peer evaluation and publication.
Consequently, this led to a surge of interest among researchers worldwide, prompting investigations into the suggested material. Notably, this involved research efforts in multiple US national laboratories and three universities in China.
While certain superconducting materials are already present in applications such as medical MRI machines and a subset of quantum computers, they exclusively exhibit their superconducting attributes under exceedingly low temperatures, rendering them impractical for widespread utilization.
The South Korean researchers last week said they found a superconductor that works at room temperature, which has long been considered a holy grail for scientists in the field.
The researchers also published a recipe for making the material – dubbed LK-99 – which involves taking a relatively common mineral called lead apatite and introducing a small number of copper atoms into it.
The South Korean researchers published two papers – one initial paper with three authors and a second, more detailed paper with six authors that included only two of the authors from the first paper.
One of the authors contacted by Reuters responded to a request for comment.
Physicists interviewed by Reuters said the good news is that there is no law of physics that says a room-temperature superconductor cannot exist, and the material described by the South Korean team is easy to grow, meaning other researchers should be able to start getting results as soon as this week.
The gold standard for proof of discovery is other labs reliably replicating the South Korean researchers’ findings.
Researchers from at least three Chinese universities have in recent days said they produced versions of LK-99 with varying results.
One team from the Huazhong University of Science and Technology posted a video purporting to show the material levitating over a magnet, which is important because true superconductors can float over a magnet in any orientation, without spinning like a compass.
But another team, from Qufu Normal University, said they did not observe zero resistance, one of the required characteristics of a superconductor. A third, from the Southeast University in the eastern Chinese city of Nanjing, said they measured zero resistance, but only at a temperature of 110 Kelvin (-163 degree Celsius).
On Thursday, South Korean experts said they would set up a committee to verify the claims.
Eric Toone, a scientist-turned-investor at Bill Gates’s Breakthrough Energy Ventures, said he is monitoring any peer review and reproduction efforts by reputable labs.
“The measurements you need to verify or to demonstrate superconductivity are very difficult to make,” said Toone. “It’s completely game changing if it’s right, but until we have more validation, we just have to be patient.”
You can be fooled
The possible bad news for LK-99 is that the superconducting field is full of materials that hold promise at first but fall apart under scrutiny. Researchers even have a handy name for them – unidentified superconducting objects.
“We call them USOs,” said Mike Norman, a condensed matter physicist at Argonne National Laboratory. “There’s a long history of USOs going a long way back, including some very famous people who thought they had a superconductor and they didn’t. It’s like anything in science – you can be fooled. Even good people can be fooled.”
Norman said the original papers had problems. Some may have been honest typographical mistakes from rushing to post the research, but more troubling was a lack of data over a broad temperature range to show how the material behaves when it is in a superconducting state and when it is not.
“People often use that method to show how much of the sample is actually a superconductor and how much of it is not,” Norman said.
Other researchers have also found reasons for caution. Sinéad Griffin, a solid-state physicist and staff scientist at Lawrence Berkeley National Laboratory, used a U.S. Department of Energy supercomputer to simulate the proposed material.
Griffin found that inserting copper atoms into lead apatite caused the material’s atoms to rearrange in an unexpected way that resembles existing superconductors. But that effect depends on the copper atoms going to a spot that they don’t naturally want to go, which could make it harder to produce the material in bulk quantities.
Griffin cautioned that her simulation has limits – it cannot conclusively prove that the material is a superconductor, and the work assumed that researchers can place copper atoms into the lead apatite with perfect precision. In the real world, that’s unlikely and could have a big effect on the material.
And even if LK-99 does turn out to be a room-temperature superconductor, it will still take time to determine how useful it might be, said Michael Fuhrer, a professor of physics at Monash University in Melbourne, Australia. For example, Fuhrer said no data was provided on how much electrical current the material might be able to carry and still be a superconductor, a key question for improving power grids.
Still, Fuhrer and other physicists said the results are worth studying given all that remains unknown about superconductors and the possibility that they could be discovered serendipitously in a common material.
“There’s lots and lots of minerals out there that we haven’t looked at yet,” said Argonne’s Norman. “And there’s probably some very interesting physics hiding in these minerals.”