Scientists at the Department of Energy's SLAC National Accelerator Laboratory and Stanford University have made the first nickel oxide material that shows clear signs of superconductivity - the ability to transmit electrical current with no loss.

Also known as a nickelate, it's the first in a potential new family of unconventional superconductors that's very similar to the copper oxides, or cuprates, whose discovery in 1986 raised hopes that superconductors could someday operate at close to room temperature and revolutionize electronic devices, power transmission and other technologies. Those similarities have scientists wondering if nickelates could also superconduct at relatively high temperatures.

At the same time, the new material seems different from the cuprates in fundamental ways - for instance, it may not contain a type of magnetism that all the superconducting cuprates have - and this could overturn leading theories of how these unconventional superconductors work. After more than three decades of research, no one has pinned that down.

The experiments were led by Danfeng Li, a postdoctoral researcher with the Stanford Institute for Materials and Energy Sciences at SLAC, and described in Nature.

"This is a very important discovery that requires us to rethink the details of the electronic structure and possible mechanisms of superconductivity in these materials," said George Sawatzky, a professor of physics and chemistry at the University of British Columbia who was not involved in the study but wrote a commentary that accompanied the paper in Nature. "This is going to cause an awful lot of people to jump into investigating this new class of materials, and all sorts of experimental and theoretical work will be done."

A difficult path
Ever since the cuprate superconductors were discovered, scientists have dreamed of making similar oxide materials based on nickel, which is right next to copper on the periodic table of the elements.

But making nickelates with an atomic structure that's conducive to superconductivity turned out to be unexpectedly hard.

"As far as we know, the nickelate we were trying to make is not stable at the very high temperatures - about 600 degrees Celsius - where these materials are normally grown," Li said. "So we needed to start out with something we can stably grow at high temperatures and then transform it at lower temperatures into the form we wanted."

He started with a perovskite - a material defined by its unique, double-pyramid atomic structure - that contained neodymium, nickel and oxygen. Then he doped the perovskite by adding strontium; this is a common process that adds chemicals to a material to make more of its electrons flow freely.

This stole electrons away from nickel atoms, leaving vacant "holes," and the nickel atoms were not happy about it, Li said. The material was now unstable, making the next step - growing a thin film of it on a surface - really challenging; it took him half a year to get it to work.

'Jenga chemistry'
Once that was done, Li cut the film into tiny pieces, loosely wrapped it in aluminum foil and sealed it in a test tube with a chemical that neatly snatched away a layer of its oxygen atoms - much like removing a stick from a wobbly tower of Jenga blocks. This flipped the film into an entirely new atomic structure - a strontium-doped nickelate.

"Each of these steps had been demonstrated before," Li said, "but not in this combination."

He remembers the exact moment in the laboratory, around 2 a.m., when tests indicated that the doped nickelate might be superconducting. Li was so excited that he stayed up all night, and in the morning co-opted the regular meeting of his research group to show them what he'd found. Soon, many of the group members joined him in a round-the-clock effort to improve and study this material.

Further testing would reveal that the nickelate was indeed superconducting in a temperature range from 9-15 kelvins - incredibly cold, but a first start, with possibilities of higher temperatures ahead.

More work ahead
Research on the new material is in a "very, very early stage, and there's a lot of work ahead," cautioned Harold Hwang, a SIMES investigator, professor at SLAC and Stanford and senior author of the report. "We have just seen the first basic experiments, and now we need to do the whole battery of investigations that are still going on with cuprates."

Among other things, he said, scientists will want to dope the nickelate material in various ways to see how this affects its superconductivity across a range of temperatures, and determine whether other nickelates can become superconducting. Other studies will explore the material's magnetic structure and its relationship to superconductivity.

Research paper

Related Links
SLAC National Accelerator Laboratory
Powering The World in the 21st Century at Energy-Daily.com

Tweet

Thanks for being here; We need your help. The SpaceDaily news network continues to grow but revenues have never been harder to maintain. With the rise of Ad Blockers, and Facebook - our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don't have a paywall - with those annoying usernames and passwords. Our news coverage takes time and effort to publish 365 days a year. If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
SpaceDaily Contributor $5 Billed Once credit card or paypal		SpaceDaily Monthly Supporter $5 Billed Monthly paypal only

Breakthrough enables storage and release of mechanical waves without energy loss
New York NY (SPX) Sep 02, 2019
Light and sound waves are at the basis of energy and signal transport and fundamental to some of our most basic technologies - from cell phones to engines. Scientists, however, have yet to devise a method that allows them to store a wave intact for an indefinite period of time and then direct it toward a desired location on demand. Such a development would greatly facilitate the ability to manipulate waves for a variety of desired uses, including energy harvesting, quantum computing, structural-integrit ... read more