New technique for analyzing cuprate superconductors earns its stripes

One of the greatest mysteries in condensed matter physics is the exact relationship between charge order and superconductivity in cuprate superconductors. In superconductors, electrons move freely through the material – there is zero resistance when the superconductor is cooled below its critical temperature. But cuprates simultaneously exhibit superconductivity and charge order in patterns of alternating stripes. This is paradoxical, because charge order describes areas of confined electrons. How can superconductivity and charge order coexist?

Now, researchers at the University of Illinois at Urbana-Champaign, together with scientists at the SLAC National Accelerator Laboratory, have shed new light on how these disparate states can exist adjacent to one another. Illinois Physics post-doctoral researcher Matteo Mitrano, physics professor Peter Abbamonte and their team did this by applying a new x-ray scattering technique, time-resolved resonant soft x-ray scattering, taking advantage of the state-of-the-art equipment at SLAC.

The technique allowed the scientists to probe the striped charge order phase with an unprecedented energy resolution, representing the first time this has been done at an energy scale relevant to superconductivity. The researchers report their findings in a paper in Science Advances.

They measured the fluctuations of charge order in a prototypical copper-oxide superconductor – La_2−xBa_xCuO₄ (LBCO) – and found the fluctuations had an energy that matched the material's superconducting critical temperature. This implies that superconductivity in this material – and by extrapolation, in the cuprates – may be mediated by charge-order fluctuations.

The researchers further demonstrated that if the charge order melts, the electrons in the system will reform the striped areas of charge order within tens of picoseconds. As it turns out, this process obeys a universal scaling law. To understand what they were seeing in their experiment, Mitrano and Abbamonte turned to Illinois physics professor Nigel Goldenfeld and his graduate student Minhui Zhu, who were able to apply theoretical methods borrowed from soft condensed matter physics to describe the formation of the striped patterns.

The significance of this mystery can be understood within the context of research in high-temperature superconductors (HTS), specifically the cuprates – layered materials that contain copper complexes. The cuprates were some of the first discovered HTS and have significantly higher critical temperatures than ‘ordinary’ superconductors (e.g. aluminum and lead superconductors have a critical temperature below 10K). In the 1980s, the cuprate LBCO was found to have a superconducting critical temperature of 35K (-396°F).

Not only was that discovery rewarded with a Nobel Prize, but it precipitated a flood of research into the cuprates. Over time, scientists found experimental evidence of inhomogeneities in LBCO and similar materials: insulating and metallic phases that were coexisting. In 1998, Illinois physics professor Eduardo Fradkin, Stanford professor Steven Kivelson and others proposed that Mott insulators – materials that ought to conduct under conventional band theory but insulate due to repulsion between electrons – are able to host stripes of charge order and superconductivity. La₂CuO₄, the parent compound of LBCO, is an example of a Mott insulator. As barium (Ba) is added to that compound, replacing some lanthanum (La) atoms, stripes form due to the spontaneous organization of holes – vacancies of electrons that act like positive charges.

Still, other questions regarding the behavior of the stripes remained. Are the areas of charge order immobile? Do they fluctuate?

"The conventional belief is that if you add these doped holes, they add a static phase which is bad for superconductivity – you freeze the holes, and the material cannot carry electricity," says Mitrano. "If they are dynamic – if they fluctuate – then there are ways in which the holes could aid high-temperature superconductivity."

To understand what exactly the stripes are doing, Mitrano and Abbamonte conceived of an experiment to melt the charge order and observe the process of its reformation in LBCO. Mitrano and Abbamonte reimagined a measurement technique called resonant inelastic x-ray scattering, by adding a time-dependent protocol to observe how the charge order recovers over a duration of 40 picoseconds. The team shot a laser at the LBCO sample, imparting extra energy into the electrons to melt the charge order and introduce electronic homogeneity.

"We used a novel type of spectrometer developed for ultra-fast sources, because we are doing experiments in which our laser pulses are extremely short," Mitrano explains. "We performed our measurements at the Linac Coherent Light Source at SLAC, a flagship in this field of investigation. Our measurements are two orders of magnitude more sensitive in energy than what can be done at any other conventional scattering facility."

"What is innovative here is using time-domain scattering to study collective excitations at the sub-meV energy scale," adds Abbamonte. "This technique was demonstrated previously for phonons. Here, we have shown the same approach can be applied to excitations in the valence band."

The first significant result of this experiment is that the charge order does in fact fluctuate, moving with an energy that almost matches the energy established by the critical temperature of LBCO. This suggests that Josephson coupling may be crucial for superconductivity.

The idea behind the Josephson effect, discovered by Brian Josephson in 1962, is that two superconductors can be connected via a weak link, typically an insulator or a normal metal. In this type of system, superconducting electrons can leak from the two superconductors into the weak link, generating within it a current of superconducting electrons.

Josephson coupling provides a possible explanation for the coupling between superconductivity and striped regions of charge order, wherein the stripes fluctuate such that superconductivity leaks into the areas of charge order, which act as the weak links.

After melting the charge order, Mitrano and Abbamonte measured the recovery of the stripes as they evolved over time. As the charge order approached its full recovery, it followed an unexpected time dependence. This result was nothing like what the researchers had encountered in the past. What could possibly explain this?

The answer is borrowed from the field of soft condensed matter physics, and more specifically from a scaling law theory Goldenfeld had developed two decades prior to describe pattern formation in liquids and polymers. Goldenfeld and Zhu demonstrated that the stripes in LBCO recover according to a universal, dynamic, self-similar scaling law.

"By the mid-1990s, scientists had an understanding of how uniform systems approach equilibrium, but how about stripe systems? I worked on this question about 20 years ago, looking at the patterns that emerge when a fluid is heated from below, such as the hexagonal spots of circulating, upwelling white flecks in hot miso soup," explains Goldenfeld. "Under some circumstances these systems form stripes of circulating fluid, not spots, analogous to the stripe patterns of electrons in the cuprate superconductors. And when the pattern is forming, it follows a universal scaling law. This is exactly what we see in LBCO as it reforms its stripes of charge order."

Through their calculations, Goldenfeld and Zhu were able to elucidate the process of time-dependent pattern reformation in Mitrano and Abbamonte's experiment. The stripes reform with a logarithmic time dependence – a very slow process. Adherence to the scaling law in LBCO further implies that it contains topological defects, or irregularities in its lattice structure. This is the second significant result from this experiment.

"It was exciting to be a part of this collaborative research, working with solid-state physicists, but applying techniques from soft condensed matter to analyze a problem in a strongly correlated system, like high-temperature superconductivity," says Zhu. "I not only contributed my calculations, but also picked up new knowledge from my colleagues with different backgrounds, and in this way gained new perspectives on physical problems, as well as new ways of scientific thinking."

In future research, Mitrano, Abbamonte and Goldenfeld plan to further probe the physics of charge order fluctuations, with the goal of completely melting the charge order in LBCO to observe the physics of stripe formation. They also plan similar experiments with other cuprates, including yttrium barium copper oxide compounds, better known as YBCO.

Goldenfeld sees this and future experiments as ones that could catalyze new research in HTS. "What we learned in the 20 years since Eduardo Fradkin and Steven Kivelson's work on the periodic modulation of charge is that we should think about the HTS as electronic liquid crystals," he says. "We're now starting to apply the soft condensed matter physics of liquid crystals to HTS to understand why the superconducting phase exists in these materials."

This story is adapted from material from the University of Illinois at Urbana-Champaign, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.