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New materials for quantum technologies

Solids with special symmetries for quantum and spintronics applications

2021-12-23 – News from the Physics Department

While conventional electronics relies on the transport of electrons, components that convey spin information alone may be many times more energy efficient. Physicists at the Technical University of Munich (TUM) and the Max Planck Institute for Solid State Research in Stuttgart have now made an important advance in the development of novel materials for such components. These materials may also be the key to quantum computers that are less susceptible to interference.

Marc A. Wilde investigates materials with special symmetries, such as manganese-silicon
Marc A. Wilde investigates materials with special symmetries, such as manganese-silicon, in the laboratory of the TUM chair for Experimental Physics on the Topology of Correlated Systems. – Image: Astrid Eckert / TUM

Hopes ran high when the first representatives of a new class of materials – topological insulators – were discovered some 15 years ago. Researchers predicted that the unique electronic structure of these materials would give rise to special properties on their surface, such as energy-efficient information transmission, which could facilitate the development of novel electronic components in a wide range of applications.

But to date, these possibilities could not be readily modified and controlled in applications. Despite the greatest of efforts, technological exploitation has been a long time coming. This may be about to change thanks to the discovery made by a team headed by Christian Pfleiderer, professorship for the Topology of Correlated Systems at the Technical University of Munich.

The search for crossings

In atoms, electrons occupy the various atomic orbitals up to a maximum energy. Each orbital corresponds to a fixed energy level. In solids, the atomic orbitals overlap, and the energy levels depend on the direction of motion and the wavelength of the electrons. The energy levels for different directions of motion and wavelengths vary within a characteristic range referred to as an energy band.

While the energy levels of the orbitals in an atom increase in a specific order, in solids the order of the energy levels, which stem from different atomic orbitals, may also be reversed depending on the direction of motion and the wavelength of the electrons.

The orientation of the energy levels originally associated with different orbitals may thus intersect for certain directions of motion and wavelengths. In other words, the energies of different orbitals are identical where they intersect. Of particular interest are materials in which these crossings appear at the level of the electrons responsible for conductivity. Physicists refer to this level as the Fermi energy.

The discovery of topological materials

Crossings between energy bands of real materials have been known since the 1930s. However, except in very rare cases, they cancel by the mutual repulsion of the electrons. This effect leads to gaps in the energy bands precisely at the expected crossings. Since all known examples of crossings in the band structure occurred far from the Fermi energy, they were regarded merely as a trivial curiosity.

All of this changed with the discovery of topological insulators in which the electronic structure of the material surface produces crossings exactly at the Fermi energy. Further observations revealed that these crossings are particularly stable because of the unique character of the electrons’ quantum mechanical wave function, which prevents cancellation through electron repulsion.

Transferring information without loss of energy

The fact that crossings of topological insulator surfaces are always at the Fermi level leads to special properties of the electrical conductivity, which allow electric charges and spin information to be transferred without any loss of energy. However, it soon became apparent that topological insulators are very sensitive to material impurities, which effectively short-circuit the surface properties and prevent useful technological implementations.

However, the discovery of topological insulators triggered an intensive and systematic search that ultimately uncovered many bulk materials with topological crossings between the energy bands inside the materials. Examples include Weyl metals, Dirac metals, and Chern insulators, among many others. Scientists expect that the crossings inside these materials will result in special properties on the surface that are amenable to technological exploitation.

Unfortunately, researchers have not been able to predict whether topological crossings in any of the known materials are exactly at the Fermi level. This was because the crossings known so far occured only at discrete points or along specific lines, meaning that they coincide with the Fermi level merely by chance.

But the last point is crucial for technical exploitation. Moreover, to be able to switch crossing points on and off by simple means in applications seemed completely out of reach.

Switchable by a magnetic field

A Möbius strip is cut with the help of a magnetic field
A magnetic field may be used to switch off certain electronic properties in solids like manganese silicon – similar to a Möbius strip, it may only be transformed into a normal circular strip by cutting it with scissors. – Image: Christoph Hohmann / MCQST

The scientists headed by Dr. Marc Wilde in Prof. Pfleiderer’s team have now demonstrated that there are materials with planes through which the bands always pass in pairs. These are known as nodal planes and make localizing crossings at the Fermi level easy. They are always exactly where the conduction band edges pass through such a plane. One of the first examples are single-crystals of manganese-silicon.

Together with Dr. Andreas Schnyder at the Max Planck Institute for Solid State Research in Stuttgart, the research team successfully elucidated the theoretical foundations for this behavior.

“An essential prerequisite is the presence of so-called ‘non-symmorphic’ symmetries. In manganese silicon, this is a twist in the arrangement of the atoms,” says Andreas Schnyder. “But that’s not all,” says Marc Wilde, “We were also able to show that magnetization in these kinds of materials can cancel the crucial symmetries and, as such, the nodal planes. The magnetization direction is effectively like a pair of scissors that we can use to cut through the Möbius strip.”

Building on this insight, Andreas Schnyder and his colleagues in Stuttgart conducted a comprehensive analysis of all known classes of crystal structures to identify those with the same properties. This is now the basis for future targeted searches for comparable materials.

Unusual properties, significant benefits

“Using manganese silicon as an example together with the recently developed theoretical principles, we may now select and optimize materials in a concerted effort,” says Christian Pfleiderer. “These new materials could enable not only much more energy-efficient electronic devices, but also absolutely novel applications in which we use external magnetic fields to control the effects of magnetization on nodal planes.”

“In this way,” Pfleiderer hopes, “these materials might even facilitate topological quantum computing in the future. Because of the characteristics of the crossing points, corresponding QBits would be much less sensitive to interference.” Quantum computers built on this basis might even shake off the requirement of operating at temperatures near absolute zero.

Dr. Andreas Battenberg
Changes in the electronic band structure of manganese silicon cause changes in the magnetic properties of the sample (bright cube).
Changes in the electronic band structure of manganese silicon cause changes in the magnetic properties of the sample (bright cube). These can be measured using a highly sensitive cantilever torque sensor (brown). – Image: Matthias Dodenhöft / TUM


Symmetry-enforced topological nodal planes at the Fermi surface of a magnet
Marc A. Wilde, Matthias Dodenhöft, Arthur Niedermayr, Andreas Bauer, Moritz M. Hirschmann, Kirill Alpin, Andreas P. Schnyder, and Christian Pfleiderer

More information

The work was funded by the European Research Council under the TOPFIT and ExQuiSid advanced grants, the German Research Foundation (DFG) under the transregional Collaborative Research Center TRR80, the Collaborative Research Program SPP 2137 and the Cooperation Program with the Czech Science Foundation (GACR), as well as the Excellence Initiative of the German Federal and State Governments under the Cluster of Excellence Munich Center for Quantum Science and Technology. Marc A. Wilde, Andreas Bauer and Christian Pfleiderer are members of the Center for Quantum Engineering (ZQE) at the Technical University of Munich, which is currently being established on the Garching research campus.


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