Despite a quarter-century of research since the discovery of the first high-temperature superconductors, scientists still don't have a clear picture of how these materials are able to conduct electricity with no energy loss. Studies to date have focused on finding long-range electronic and magnetic order in the materials, such as patterns of electron spins, based on the belief that this order underlies superconductivity. But a new study conducted by researchers from the US Department of Energy's (DOE) Brookhaven National Laboratory and Oak Ridge National Laboratory (ORNL) and published in the Proceedings of the National Academy of Sciences is challenging this notion.
The study details how an iron-telluride material related to a family of high-temperature superconductors develops superconductivity with no long-range electronic or magnetic order when ‘doped’ with a small amount of sulfur. In fact, the material displays a liquid-like magnetic state consisting of two co-existing and competing disordered magnetic phases, which appears to precede-and may be linked to its superconducting behavior.
"Our results challenge a number of widely accepted paradigms into how unconventional superconductors work," said the study's lead researcher, Brookhaven physicist Igor Zaliznyak. "I believe that we have uncovered an important clue to the nature of magnetism and its connections to superconductivity in the iron-based superconductors."
This advance could open up a new avenue for exploring the emergence of a property with great potential for widespread use. Conventional superconductors, which must be chilled to extremely low temperatures to operate, already play a key role in many modern technologies, from medical magnetic resonance imaging (MRI) to maglev trains. New clues about the function of unconventional superconductors, which do not need to be super-cooled, could potentially lead to many more technologies, including zero-energy-loss power transmission lines and other important energy applications. Indeed, other materials with a similar structure to the material investigated in this study can operate as superconductors at these ‘warmer’ temperatures, so understanding the physics of this close relative has many important implications.
"Our results challenge a number of widely accepted paradigms into how unconventional superconductors work."Brookhaven physicist Igor Zaliznyak
Zaliznyak and his collaborators studied the unconventional superconducting material using neutron scattering at ORNL's High Flux Isotope Reactor. They created maps of magnetic scattering for the material at several temperatures and as the material was doped with a small amount of sulfur. Like a composite photograph made of several separate photos, the maps stitch together many ‘snapshots’ of the magnetic order in the material.
They found that the ordering was extremely local in nature, existing for only an instant before changing – a characteristic of a liquid-like behavior. In fact, the results revealed that a fundamental change in the local, liquid-like pattern of electronic spin correlations was the key change that accompanied the emergence of superconductivity with decreasing temperature in this material.
"The measurements reveal dynamical arrangements of magnetic moments similar to the patterns formed by square dancers on a dance floor," explained Zaliznyak. "As the temperature was reduced, the magnetic atoms appeared to change their partners; in this case, the dance move was initiated by the mobile electrons that eventually develop into the superconducting state."
In addition to offering insight into a potential mechanism for the emergence of high-temperature superconductivity, this work also provides valuable insight into the nature of liquids. Despite being among the most common condensed matter systems, liquids are still poorly understood at the microscopic level. In fact, the dynamic and fleeting nature of the local order in liquids is what makes them particularly difficult to study.
The idea that liquids can be a mixture of two distinct liquid ‘species’ that have different local structures and densities dates back to the late 19th century. Even now, the possible existence of different liquid ‘polymorphs’ in simple molecular fluids, and liquid-liquid phase transitions between them, continues to receive considerable attention in the research world. But the issue has not been settled, mainly because the competition between different liquid phases only arises at very low temperatures, often far below freezing.
"In some materials, however, such competition arises quite naturally in systems of electronic magnetic moments, where the development of magnetic order is hindered by competing interactions," said Zaliznyak. "In these cases, the material remains disordered even at temperatures much lower than the energy of magnetic interactions, thus producing an electronic spin liquid state. Our results studying the spin system of sulfur-doped FeTe provide a rare experimental example of such a liquid polymorphism."
The group's results also refute another set of widely accepted views of the electronic states in metals, where electrons are only allowed to occupy a certain set of rigid energy bands. The spin-liquid state they discovered seems to reflect the existence of new electron-orbital hybrids, likely resulting from the sulfur doping but also brought on by changes in temperature. "This is a surprising discovery that calls for a profound revision of the 'tight binding' model of electron orbitals," said Zaliznyak.
What is more, he and his group may also have found an explanation for mysterious neutron scattering patterns observed by other groups studying iron-based superconductor samples. "It appears that all of the variety in the neutron patterns that have been observed in these materials can be well described by our spin-liquid model," he said. "They all manifest with very similar local correlations, revealing that we may have found an amazing intrinsic universality among them."
This story is adapted from material from Brookhaven National Laboratory, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.