New study detects quantum singularity in cuprate superconductor

Among all the curious states of matter that can coexist in a quantum material, jostling for pre-eminence as temperature, electron density and other factors change, some scientists think a particularly weird juxtaposition called the quantum critical point (QCP) exists at a single intersection of factors.

"Quantum critical points are a very hot issue and interesting for many problems," says Wei-Sheng Lee, a staff scientist at the US Department of Energy's SLAC National Accelerator Laboratory and investigator with the Stanford Institute for Materials and Energy Sciences (SIMES). "Some suggest that they're even analogous to black holes in the sense that they are singularities – point-like intersections between different states of matter in a quantum material – where you can get all sorts of very strange electron behavior as you approach them."

In a paper in Nature Physics, Lee and his collaborators report that they have now found strong evidence that QCPs and their associated fluctuations do exist. They used a technique called resonant inelastic X-ray scattering (RIXS) to probe the electronic behavior of a copper oxide material, or cuprate, that conducts electricity with perfect efficiency at relatively high temperatures.

These so-called high-temperature superconductors are a bustling field of research because they could give rise to zero-waste transmission of energy, energy-efficient transportation systems and other futuristic technologies, although no one yet understands the underlying microscopic mechanism behind high-temperature superconductivity. Whether QCPs exist in cuprates is also a hotly debated issue.

In experiments at the UK's Diamond Light Source, the team chilled the cuprate to temperatures below 90K (-183°C), where it became superconducting. They then focused their attention on what's known as charge order – alternating stripes in the material where electrons and their negative charges are denser or sparser.

The scientists excited the cuprate with X-rays and measured the X-ray light that scattered into the RIXS detector. This allowed them to map out how the excitations propagated through the material in the form of subtle vibrations, or phonons, in the material's atomic lattice, which are hard to measure and require very high-resolution tools.

At the same time, the X-rays and the phonons can excite electrons in the charge order stripes, causing the stripes to fluctuate. Since the data obtained by RIXS reflects the coupling between the behavior of the charge stripes and the behavior of the phonons, observing the phonons allowed the researchers to measure the behavior of the charge order stripes as well.

What the scientists expected to see is that when the charge order stripes grew weaker, their excitations would also fade away. "But what we observed was very strange," Lee said. "We saw that when charge order became weaker in the superconducting state, the charge order excitations became stronger. This is a paradox because they should go hand in hand, and that's what people find in other charge order systems.

"To my knowledge this is the first experiment about charge order that has shown this behavior. Some have suggested that this is what happens when a system is near a quantum critical point, where quantum fluctuations become so strong that they melt the charge order, much like heating ice increases thermal vibrations in its rigid atomic lattice and melts it into water. The difference is that quantum melting, in principle, occurs at zero temperature."

In this case, Lee explained, the unexpectedly strong charge order excitations seen with RIXS were manifestations of those quantum fluctuations. The team is now studying these phenomena at a wider range of temperatures and at different levels of doping – where compounds are added to change the density of freely moving electrons in the material – to see if they can nail down exactly where the quantum critical point could be in this material.

Thomas Devereaux, a theorist at SIMES and senior author of the paper, noted that many phases of matter can be intertwined in cuprates and other quantum materials. "Superconducting and magnetic states, charge order stripes and so on are so entangled that you can be in all of them at the same time. But we're stuck in our classical way of thinking that they have to be either one way or another."

Here, he said, "We have an effect, and Wei-Sheng is trying to measure it in detail, trying to see what's going on."

This story is adapted from material from the SLAC National Accelerator 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.