Tag: quantum material

Researchers use Argonne X-rays to better understand the phases of a quantum material

Researchers use Argonne X-rays to better understand the phases of a quantum material

Understanding the mysterious properties of materials requires the ability to precisely measure the atoms of those materials as they go through changes. For example, scientists are not certain why quantum materials become superconducting at low temperatures. To find out, they need the most advanced instruments available to catch the atoms in the act. 

The Advanced Photon Source (APS), a U.S. Department of Energy (DOE) Office of Science user facility at DOE’s Argonne National Laboratory, is one such instrument. Or rather, it’s more than 70 such instruments, able to explore materials with a variety of X-ray techniques and, when needed, combine those techniques to deliver a more comprehensive result. 

“The integration of the improved beams, the sample environment and the combination of techniques available at the APS will make further breakthroughs with these materials possible.” – Philip J. Ryan, Argonne National Laboratory

Recently a collaboration between DOE’s SLAC National Accelerator Laboratory and Argonne used the ultrabright X-ray beams of the APS to uncover tantalizing insights about strontium titanate, a material that was once used as a diamond substitute in jewelry and now has the potential to unlock our understanding of an array of quantum behaviors.

The research team built extremely thin, flexible strontium titanate membranes and, using a sample apparatus developed by the beamline staff, stretched it, in the process turning on what is known as a ferroelectric state. In that state, the material generates its own electric field, somewhat similar to how a permanent magnet generates its own magnetic field. APS X-ray beams were able to capture the movement of the ions in the material as it was repeatedly strained to ​“tune” the material in and out of a ferroelectric state.

“Our apparatus allows us to precisely control the strain placed on the material,” said Yongseong Choi, a physicist who works at the APS. ​“That and the combination of X-ray techniques we used gave us an extraordinary insight into the behavior of this material as it transitions through controlled phases.”

The team used two beamlines at the APS. They performed linear X-ray dichroism at beamline 4-ID-Dto determine the change in the spacing between the atoms, and X-ray diffraction at beamline 6-ID-Bto determine the strain on the material. Combining these results enabled the team to precisely track the arrangement of electrons in the material as its positively charged titanium ions were separated from its negatively charged oxygen ions, creating an electric field. 

While the ability to turn on ferroelectricity — as well as superconductivity through the addition of impurities — makes strontium titanate promising for applications in next generation computing, data storage and superconducting devices, this well-known material also offers us a prototype to study fundamental quantum behaviors in a plethora of structurally similar materials.

What the research team found when they lowered the material temperature to cryogenic temperatures — lower than 200 degrees Fahrenheit below zero – was a transition into a quantum state. In this state, quantum fluctuations — random, temporary changes in energy levels — present themselves. At lower temperatures under applied strain strontium titanate began to shift to a state in which quantum fluctuations, rather than thermal motion, drove the order of nearby ions in the material.

Stretching the material is an excellent tuning parameter altering those quantum fluctuations. Introducing strain as a control element gives scientists more ways to explore the material’s properties. A better understanding of this transition could help researchers tailor strontium titanate and other quantum materials for different applications, such as microelectronic switches or capacitors.

Read more on APS website

Image: An artist’s illustration of X-ray probes of strontium titanate.

Credit: Greg Stewart/SLAC National Accelerator Laboratory

Quantum heat dynamics toggled by magnetic fields

Quantum heat dynamics toggled by magnetic fields

Scientists discover unknown mechanism of heat conduction in quantum material

The ability to conduct heat is one of the most fundamental properties of matter, crucial for engineering applications. Scientists know well how conventional materials, such as metals and insulators, conduct heat. However, things are not as straightforward under extreme conditions such as temperatures close to absolute zero combined with strong magnetic fields, where strange quantum effects begin to dominate. This is particularly true in the realm of quantum materials. Researchers from the Helmholtz-Zentrum Dresden-Rossendorf (HZDR), University of Bonn, and Centre national de la recherche scientifique (CNRS) now exposed the semimetal zirconium pentatelluride (ZrTe5) to high magnetic fields and very low temperatures. They found dramatically enhanced heat oscillations caused by a novel mechanism. This finding challenges the widely held belief that magnetic quantum oscillations should not be detectable in the heat transport of semimetals, as the scientists report in the journal PNAS.

The quantum material ZrTe5 belongs to the class of so-called topological semimetals. In physics, the term “topological” describes special materials that, due to their unique electronic structure, have extremely robust (“topologically protected”) conduction properties. In such materials, quantum effects can lead to unconventional and often bizarre phenomena that could play a crucial role in advancing future quantum technologies. Notably, both research and industry are currently investing considerable effort into developing quantum computers, with topological materials emerging as a promising avenue for their realization. Like ZrTe₅: it combines a rare set of non-trivial electronic properties, making it potentially relevant for high-precision electronics applications and magnetic-field sensor technologies.

“When a normal metal such as silver or copper is placed in strong magnetic fields at temperatures close to absolute zero, that is −273.15 °C, its heat conduction is expected to oscillate − a striking example of quantum mechanical dynamics of electrons in metals. This effect arises due to the existence of the so-called Fermi surface, a boundary between occupied and unoccupied energy states of electrons in a metal”, Dr. Stanisław Gałeski, currently assistant professor at Radboud University and visiting scientist at the Dresden High Magnetic Field (HLD) laboratory at HZDR, explains. “On the other hand, in semimetals, there are very few electrons available to transport heat, and as such, heat conduction is widely believed to be dominated by phonons − emergent particles that represent crystal lattice vibrations. As such, quantum oscillations should not be detectable in the transport of heat”, Gałeski sums up more traditional expectations. However, several recent experiments have found giant quantum oscillations in the heat conduction of semimetals, questioning the mechanism of heat transport.

Read more on HZDR website

Image: Artistic visualization of a crystalline rod made of the semimetal ZrTe5. There is a heat gradient from one end to the other. In its center, giant oscillations in its heat conduction are toggled by the magnetic field, which is generated by the electromagnet below.

Credit: B. Schröder/HZDR