Cuprate Materials' Fluctuating Stripes May Be Linked to High-temp Superconductivity
December 1, 2017 | SLAC National Accelerator LaboratoryEstimated reading time: 4 minutes
In conventional electrical conductors, current is transmitted by electrons acting individually. But in superconductors, electrons pair up to transmit current with virtually no loss.
For 75 years after their discovery, all known superconductors operated only at temperatures close to absolute zero, limiting the way they could be used.
That changed in 1986, when scientists discovered that cuprates could superconduct at much higher (although still quite chilly) temperatures. In fact, certain cuprate compounds are superconducting at temperatures higher than 100 kelvins, or minus 173 degrees Celsius, allowing development of superconducting technologies that can be chilled with liquid nitrogen.
But researchers are still far from their goal of finding superconductors that operate at close to room temperature for highly efficient power lines, maglev trains and other applications that could have a profound impact on society. Without a fundamental understanding of how high-temperature superconductors work, progress has been slow.
Computer modeling is a critical tool for achieving that understanding. Models are sets of mathematical equations based on physics that theorists create and continually refine to simulate a material’s behavior using computer algorithms. They check their models against observations and experimental results to make sure they’re on the right track.
In this case, the team modeled electron behavior and interactions in one of a cuprate’s copper oxide layers, which is where the interesting physics happens, said SIMES staff scientist Brian Moritz. The calculations were run on Stanford’s Sherlock supercomputer cluster at SLAC and at the DOE’s National Energy Research Scientific Computing Center in Berkeley.
The results were in good agreement with data from neutron scattering experiments on a variety of cuprates, the scientists said, confirming that their simulations accurately capture the electronic physics of these materials.
A More Accurate Model
This is the first time the high-temperature behavior of cuprates has been simulated with a realistic model that covers a large enough area of the material to see fluctuating stripes, Huang said. This larger scale also makes the calculations more accurate.
“There was a fine balance we needed to strike,” he said. “These are extremely computationally demanding calculations. But if you simulate the behavior of smaller areas, you won’t be able to see any stripes that emerge. That was the primary limitation of previous studies.”
The simulations show that stripes emerge at temperatures up to 600 degrees Celsius and in a wide range of doping conditions, where compounds are added to a material to tweak its electronic behavior, and so they appear to be a universal trait of cuprate superconductors, the researchers said.
“The idea that there are fluctuating stripes in cuprates is not new, but it has been a controversial topic for many years,” Huang said. “What’s new here is that we can support their existence using unbiased computation on a realistic model of these materials.”
One thing the study does not do, he added, is answer the question of whether or how the fluctuating stripes figure into superconductivity: “That is the direction we want to head toward.”
In addition to SLAC and Stanford, contributors to this study came from the University of Tennessee, Knoxville and its Joint Institute for Advanced Materials. The research was funded by the DOE Office of Science.
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