Extremely Robust & Ultra-Sensitive: Topological Quantum Device Produced
A significant breakthrough has been achieved by quantum physicists from Dresden and Würzburg. They’ve created a semiconductor device where exceptional robustness and sensitivity are ensured by a quantum phenomenon. This topological skin effect shields the functionality of the device from external perturbations, allowing for measurements of unprecedented precision. This remarkable advance results from the clever arrangement of contacts on the aluminum-gallium-arsenide material. It unlocks potential for high-precision quantum modules in topological physics, bringing these materials into the semiconductor industry's focus. Published in Nature Physics, these findings mark a major milestone.
Topological Phenomenon in a Semiconductor Device
Semiconductor devices are tiny switching components that control electron flow in modern electronic devices. They power ubiquitous high-tech items like cell phones, laptops, and car sensors, as well as state-of-the-art medical equipment. However, material impurities or temperature changes can disrupt the flow of electrons, leading to instability.
But now, theoretical and experimental physicists from the Würzburg-Dresden Cluster of Excellence ct.qmat—Complexity and Topology in Quantum Matter have developed a semiconductor device from aluminum-gallium-arsenide (AlGaAs). This device’s electron flow, usually susceptible to interference, is safeguarded by a topological quantum phenomenon. This groundbreaking research was recently detailed in the esteemed journal Nature Physics.
“Thanks to the topological skin effect, all of the currents between the different contacts on the quantum semiconductor are unaffected by impurities or other external perturbations. This makes topological devices increasingly appealing for the semiconductor industry. They eliminate the need for the extremely high levels of material purity that currently drive up the costs of electronics manufacturing,” explains Professor Jeroen van den Brink, director of the Institute for Theoretical Solid State Physics at the Leibniz Institute for Solid State and Materials Research in Dresden (IFW) and a principal investigator of ct.qmat. Topological quantum materials, known for their exceptional robustness, are ideally suited for power-intensive applications. “Our quantum semiconductor is both stable and yet highly accurate—a rare combination. This positions our topological device as a thrilling new option in sensor engineering.”
Extremely Robust and Ultra-Precise
Utilizing the topological skin effect enables new types of high-performance electronic quantum devices that could also be incredibly small. “Our topological quantum device measures about 0.1 millimeters in diameter, and can be scaled down even further with ease,” reveals van den Brink. The pioneering aspect of this achievement by the team of physicists from Dresden and Würzburg is that they were the first to realize the topological skin effect on a microscopic scale in a semiconductor material. This quantum phenomenon was initially demonstrated at a macroscopic level three years ago—but only in an artificial metamaterial, not a natural one. This is therefore the first time that a tiny, semiconductor-based topological quantum device that’s both highly robust and ultra-sensitive has been developed.
“In our quantum device, the current–voltage relationship is protected by the topological skin effect because the electrons are confined to the edge. Even in the event of impurities in the semiconductor material, the current flow remains stable,” explains van den Brink. He continues: “Moreover, the contacts can detect even the slightest fluctuations in current or voltage. This makes the topological quantum device exceptionally well suited for making high-precision sensors and amplifiers with minuscule diameters.”
Innovative Experimentation Leads to Discovery
Success was achieved by creatively arranging materials and contacts on an AlGaAs semiconductor device, inducing the topological effect under ultra-cold conditions and a strong magnetic field. “We really coaxed the topological skin effect out of the device,” van den Brink explains. The physics team employed a two-dimensional semiconductor structure. The contacts were arranged in such a way that the electrical resistance could be measured at the contact edges, directly revealing the topological effect.
United Research in Different Locations
Since 2019, ct.qmat has been investigating topological quantum materials in Würzburg and Dresden, exploring their extraordinary behavior under extreme conditions like ultra-low temperatures, high pressures, or strong magnetic fields.
The recent breakthrough is also the result of sustained collaboration among scientists at the cluster’s two locations. The new quantum device, conceived at the IFW, was a joint effort involving theoretical physicists from Universität Würzburg as well as both theoretical and experimental researchers in Dresden. After being produced in France, the device was tested in Dresden. Jeroen van den Brink and his colleagues are now dedicated to further exploring this phenomenon, aiming to leverage it for future technological innovations.
Cluster of Excellence ct.qmat
The Cluster of Excellence ct.qmat – Complexity and Topology in Quantum Matter has been jointly run by Julius-Maximilians-Universität (JMU) Würzburg and Technische Universität (TU) Dresden since 2019. Over 300 scientists from more than thirty countries and four continents study topological quantum materials that reveal surprising phenomena under extreme conditions such as ultra-low temperatures, high pressure, or strong magnetic fields. ct.qmat is funded through the German Excellence Strategy of the Federal and State Governments and is the only Cluster of Excellence in Germany to be based in two different federal states.
Wissenschaftlicher Ansprechpartner:
Prof. Jeroen van den Brink
Leibniz-Institut für Festkörper- und Werkstoffforschung Dresden
Tel: +49 351 4659-380
E-Mail: j.van.den.brink@ifw-dresden.de
Originalpublikation:
Non-Hermitian topology in a multi-terminal quantum Hall device
Ochkan, K., Chaturvedi, R., Könye, V. et al. Nat. Phys. (2024).
https://www.nature.com/articles/s41567-023-02337-4