UTMESA+MESA+ InstituteNewsSuperconductivity offers new insights into quantum material

Superconductivity offers new insights into quantum material

For the first time since the discovery of the material MnBi2Te4 (MBT), researchers at the University of Twente have successfully made it behave like a superconductor. This marks an important step in understanding MBT and is significant for future technologies, such as new methods of information processing and quantum computing.

MBT is a recently discovered material attracting attention due to its unique magnetic and topological properties. In their research, the scientists examined how electricity behaves in the material. MBT’s topological properties cause electrons to move only along the edges of the material, and in theory, they should only move in a clockwise direction. However, the experiments at Twente demonstrated that under certain conditions, the electrons can rotate both clockwise and counterclockwise.

Superconductivity

According to the researchers, this finding is crucial. Researcher Thies Jansen explains: "It may not seem like a significant difference, but the one-way electron flow is essential for creating new electronic states that enable novel ways of processing information." The researchers observed that the electrons rotated in both directions when they succeeded in making MBT act as a superconductor – a material without electrical resistance, which allowed them to study its properties under the influence of a magnetic field.

“The different rotation directions of the electrons are undesirable if we aim to use the material in quantum applications, but now that we understand how these unwanted properties emerge, we can also work on preventing them,” says Jansen.

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Thies Jansen is a PhD candidate in the Interfaces and Correlated Electron Systems (ICE) group at the Faculty of Science & Technology / MESA+. He and his fellow researchers published an article, titled ‘Josephson coupling across magnetic topological insulator MnBi2Te4’, in the scientific journal Communications Materials. The article is open-access and can be read online. Today, he defended his PhD-thesis titled 'Topology and correlations in oxides and tellurides'.

DOI: 10.1038/s43246-024-00649-3

K.W. Wesselink - Schram MSc (Kees)
Science Communication Officer (available Mon-Fri)