November 23, 2024

Breakthrough in Quantum Research Paves Way for New Generation of Light-Driven Electronics

Optics and electronic devices are linked by a quantum phenomenon
An international research group headed by Professor Ralph Claessen, quantum physicist from Würzburg and co-spokesperson of ct.qmat, has now made an essential discovery. “For the very first time, weve been able to generate and experimentally detect quasiparticles understood as excitons in a topological insulator.
Whats unusual about this, he states, is that the excitons were activated in a topological insulator– something that wasnt possible before. “This has actually opened up an entirely new line of research study for topological insulators,” includes Claessen.
Three excitons (pairs consisting of an electron and an electron hole) on the topological insulator bismuthene. Due to the honeycomb atomic structure, electrons can just flow along the edges. Credit: Pawel Holewa
For about 10 years, excitons have been investigated in other two-dimensional semiconductors and considered as information providers for light-driven parts. “For the very first time, weve handled to optically excite excitons in a topological insulator. The interaction between light and excitons implies we can expect brand-new phenomena in such materials. This principle could be used, for instance, to generate qubits,” states Claessen.
Qubits are calculating systems for quantum chips. Theyre far remarkable to conventional bits and enable to solve jobs within minutes for which traditional supercomputers would literally take years. Using light rather of electrical voltage makes it possible for quantum chips with much quicker processing speeds. The newest findings therefore lead the way for future quantum technologies and a brand-new generation of light-driven gadgets in microelectronics.
Global expertise from Würzburg
The best starting product is important– in this case bismuthene. “Its the heavy brother or sister of the miracle product graphene,” says Claessen, who initially customized the topological insulator in the lab five years earlier. “Were the international leaders in this field,” he adds. “Due to our advanced products design, the atoms of the single layer of bismuthene are organized in a honeycomb pattern, similar to graphene. The distinction is that bismuthenes heavy atoms make it a topological insulator, indicating it can carry out electrical energy along the edge without loss– even at space temperature. This cant be done by graphene.”
Animation: A light pulse on bismuthene generates exciton sets that move through the two-dimensional ultrathin layer of material. A light pulse on bismuthene produces exciton pairs that move through the two-dimensional ultrathin layer of material. Due to the fact that bismuthene is a topological insulator, the flow of existing at the edges is practically lossless.
Substantial potential.
Now that the research group has created excitons in a topological insulator for the first time, attention is being turned to the quasiparticles themselves. Scientists at ct.qmat are examining whether bismuthenes topological properties are transferred to excitons. Showing this clinically is the next milestone that the scientists have their sights on. It would even pave the way for the construction of topological qubits, which are considered especially robust compared to their non-topological equivalents.
International cooperation.
These findings arise from close collaboration amongst scientists from Bologna, Wroclaw, New York, Oldenburg and Würzburg. The 2D product samples of bismuthene were produced at JMU Würzburg.
Recommendation: “Photoswitching finger print analysis bypasses the 10-nm resolution barrier” by Dominic A. Helmerich, Gerti Beliu, Danush Taban, Mara Meub, Marcel Streit, Alexander Kuhlemann, Sören Doose and Markus Sauer, 1 August 2022, Nature Methods.DOI: 10.1038/ s41592-022-01548-6.

Excitons in the topological insulator bismuthene. Credit: Jörg Bandmann
A breakthrough in quantum research– the first detection of excitons (electrically neutral quasiparticles) in a topological insulator has actually been accomplished by an international team of researchers collaborating within the Würzburg-Dresden Cluster of Excellence ct.qmat. It was made it possible for thanks to smart material design in Würzburg, the birthplace of topological insulators.
New toolbox for solid-state physics
In their search for novel materials for future quantum innovations, one location that scientists from the Cluster of Excellence ct.qmat– Complexity and Topology in Quantum Matter– at the 2 universities in Würzburg and Dresden are focusing on is topological insulators, which make it possible for the lossless conduction of electrical existing and robust info storage. The first speculative awareness of this materials class occurred in Würzburg in 2007, triggering a worldwide research boom in solid-state physics that continues to this day.
Previous concepts for using topological insulators are based on the application of electrical voltages in order to control currents– a technique embraced from standard computer chips. If the exotic product properties are based on electrically neutral particles (which are neither favorably nor negatively charged), an electrical voltage no longer works. Such quantum phenomena, therefore, require other tools if they are to be generated at all– for instance, light.

A breakthrough in quantum research– the first detection of excitons (electrically neutral quasiparticles) in a topological insulator has been accomplished by a global group of scientists teaming up within the Würzburg-Dresden Cluster of Excellence ct.qmat. “For the very first time, weve been able to create and experimentally detect quasiparticles known as excitons in a topological insulator. Three excitons (sets consisting of an electron and an electron hole) on the topological insulator bismuthene. “For the very first time, weve handled to optically delight excitons in a topological insulator. Now that the research group has actually created excitons in a topological insulator for the first time, attention is being turned to the quasiparticles themselves.