De nouveaux indices surprenants découverts sur les superpuissances des supraconducteurs exotiques

Vue d’artiste d’un aimant en lévitation au-dessus d’un supraconducteur à haute température refroidi à l’azote liquide. Lorsqu’un aimant est placé au-dessus d’un supraconducteur, le supraconducteur repousse le champ magnétique, ce qui fait que l’aimant se repousse ou flotte.

Study exploite l’un des aimants les plus puissants de la Terre pour sonder un nouveau modèle d’un métal mystérieux.

Une équipe de recherche a découvert de nouveaux indices sur le comportement exotique des supraconducteurs non conventionnels – des dispositifs qui transportent efficacement le courant électrique avec une résistance nulle d’une manière qui défie notre compréhension antérieure de la physique.

“L’espoir est que notre travail puisse conduire à une meilleure compréhension de la supraconductivité, qui pourrait trouver des applications dans les trains de stockage d’énergie, de supercalcul et de lévitation magnétique de nouvelle génération”, a déclaré le premier auteur Nikola Maksimovic, chercheur étudiant diplômé au Berkeley Lab’s Sciences des matériaux. Division et le département de physique de l’UC Berkeley.

Les travaux pourraient également aider les chercheurs à concevoir des matériaux supraconducteurs plus puissants en ajustant leur composition chimique au niveau atomique. L’équipe, dirigée par Lawrence Berkeley National Laboratory (Berkeley Lab) en collaboration avec UC Berkeley, a rapporté ses découvertes dans la revue science

Les matériaux supraconducteurs conventionnels comme le plomb ou l’étain deviennent supraconducteurs à des températures proches de zéro sur l’échelle Kelvin, soit moins 523,4 degrés[{” attribute=””>Fahrenheit. But some unconventional superconductors like cuprates, a type of ceramic metal containing copper and oxygen, somehow become superconducting at relatively high temperatures near or above 100 Kelvin (minus 280 degrees Fahrenheit).

For decades, researchers have struggled to understand how superconducting cuprates work, in part because cuprates are difficult to grow without defects. What’s more is their powerful superconductivity is challenging to switch off – like a race car that keeps on going, even when it’s in neutral. Scientists therefore need a tool to help them understand how superconductivity evolves from different phases at the atomic level, and which formulations have the most potential for real-world applications.

Doped CeCoIn5 Samples

Image of doped CeCoIn5 samples resting on copper “puck” sample holders. (Each puck is approximately the size of a silver dollar.) The Berkeley Lab-led team used spectroscopic techniques at the Advanced Light Source to image the CeCoIn5 crystals’ superconductivity as a function of chemical composition. Credit: Image courtesy of former Berkeley Lab researcher Daniel Eilbott

So for the current study, a research team led by James Analytis focused on a material made of cerium-cobalt-indium5 (CeCoIn5) that could mimic a cuprate system. Analytis is a faculty scientist and co-investigator in the Quantum Materials program in Berkeley Lab’s Materials Sciences Division, which provided the funding for this work. He is also a physics professor at UC Berkeley.

To some, CeCoIn5 might seem like an unlikely model to study superconducting cuprates. CeCoIn5 contains neither copper nor oxygen, after all. But despite their differences, cuprates and CeCoIn5 share some key traits: They are both unconventional superconductors with electron density or “spatial symmetry” patterns resembling a four-leaf clover. Such spatial symmetry is like a map highlighting which parts of the superconductor are most densely populated by electrons.

The team also knew from other studies that the superconducting state in CeCoIn5 could be switched on and off with powerful magnets that are currently available in the laboratory, whereas the requisite magnetic fields needed to modulate cuprates far exceed those of even the most sophisticated techniques.

Turning off the superconducting state in CeCoIn5, the team reasoned, would allow them to “look under the hood,” and study how the material’s electrons behave in a normal, non-superconducting state. Since cuprates and CeCoIn5 share similar electronic density patterns, the team inferred that studying CeCoIn5 in all its different phases could provide important new clues into the origins of cuprates’ superconducting capabilities.

“CeCoIn5 is a very useful model system. It’s an unconventional superconductor whose properties are very accessible to experimental techniques at high magnetic fields, some of which are not possible in cuprates,” said first author Nikola Maksimovic, a graduate student researcher in Berkeley Lab’s Materials Sciences Division and the Analytis lab in UC Berkeley’s Physics Department.

MERLIN Beamline

The High-Resolution Spectroscopy of Complex Materials (MERLIN) beamline – aka Beamline 4.0.3 – at the Advanced Light Source (ALS) where the Berkeley Lab-led team conducted the photoemission spectroscopy experiments to measure the electronic energy structure and superconductivity of doped CeCoIn5 samples. Credit: Image courtesy of former Berkeley Lab researcher Daniel Eilbott

To begin testing the material as a potential cuprate model, the researchers grew more than a dozen single-crystals of CeCoIn5 at their Materials Sciences Division lab, and then fabricated experimental devices from those crystals at the Molecular Foundry’s National Center for Electron Microscopy facility.

They tuned some of the CeCoIn5 crystals to the magnetic state by replacing a few indium atoms with cadmium, and tuned other samples to the superconducting state by replacing indium with tin.

Maksimovic measured the electron density of these materials at the National High Magnetic Field Laboratory’s Pulsed Field Facility at Los Alamos National Laboratory using magnetic fields of up to 75 tesla, which is about 1.5 million times stronger than the Earth’s magnetic field.

Then, a team led by Alessandra Lanzara used spectroscopic techniques at Berkeley Lab’s Advanced Light Source to image the CeCoIn5 crystals’ electronic energy structure and superconductivity as a function of chemical composition. Lanzara is a senior faculty scientist and co-investigator in the Quantum Materials program in Berkeley Lab’s Materials Sciences Division and a UC Berkeley physics professor.

Much to their surprise, the researchers found that in chemical compositions where the superconductivity is strongest, the number of free electrons jumps from a small value to a large value, signifying that the material is at a transition point. (A free electron is an electron that is not permanently bound to an atom.) The researchers attributed this transition to the behavior of electrons associated with the cerium atoms.

“There are only a few materials where such a transition is suspected to occur. We have some of the clearest evidence that it actually does, and that’s pretty exciting,” Maksimovic said.

In future studies, the researchers plan to investigate how the transition in CeCoIn5 applies to other unconventional superconductors like cuprates. They also plan to investigate how the transition in CeCoIn5 may affect other physical properties of the material such as thermal conductivity.

Reference: “Evidence for a delocalization quantum phase transition without symmetry breaking in CeCoIn5” by Nikola Maksimovic, Daniel H. Eilbott, Tessa Cookmeyer, Fanghui Wan, Jan Rusz, Vikram Nagarajan, Shannon C. Haley, Eran Maniv, Amanda Gong, Stefano Faubel, Ian M. Hayes, Ali Bangura, John Singleton, Johanna C. Palmstrom, Laurel Winter, Ross McDonald, Sooyoung Jang, Ping Ai, Yi Lin, Samuel Ciocys, Jacob Gobbo, Yochai Werman, Peter M. Oppeneer, Ehud Altman, Alessandra Lanzara and James G. Analytis, 2 December 2021, Science.
DOI: 10.1126/science.aaz4566

Researchers from the National High Magnetic Field Laboratory facilities in Tallahassee, Florida, and Los Alamos, New Mexico; and from Uppsala University, Sweden, participated in the study.

The Advanced Light Source and Molecular Foundry are DOE Office of Science user facilities at Berkeley Lab.

The National High Magnetic Field Laboratory’s Pulsed Field Facility at Los Alamos National Laboratory is funded by the National Science Foundation.

This work was supported by the DOE Office of Science. Additional funding was provided by the Gordon and Betty Moore Foundation’s EPiQS Initiative.

The Gordon and Betty Moore Foundation fosters path-breaking scientific discovery, environmental conservation, patient care improvements, and preservation of the special character of the Bay Area.

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