Topological materials for information technology offer lossless transmission of signals

The TEM image shows the superstructure which is created by doping of Bi<sub>2</sub>Te<sub>3</sub> with manganese: Between the originally 5-atom-layer thick units (QL) new 7-atom-layer units are formed by self-organization in which the manganese occupies the central layers.

The TEM image shows the superstructure which is created by doping of Bi2Te3 with manganese: Between the originally 5-atom-layer thick units (QL) new 7-atom-layer units are formed by self-organization in which the manganese occupies the central layers. © G. Springholz/Uni Linz

New experiments with magnetically doped topological insulators at BESSY II have revealed possible ways of lossless signal transmission that involve a surprising self-organisation phenomenon. In the future, it might be possible to develop materials that display this phenomenon at room temperature and can be used as processing units in a quantum computer, for example. The study has been published in the renowned journal Nature.

New effects in solid-state physics are often first discovered at temperatures near absolute zero (0 Kelvin or -273 °C). Further research can then determine whether and how these phenomena can be induced at room temperature as well. So it was that superconductivity was initially observed in mercury below 4 Kelvin more than 100 years ago. Today, there are many high-temperature superconductors that conduct electrical current without resistive losses at temperatures as high as 138 Kelvin or even 200 Kelvin (the record held by H2S).

Lossless charge transport

The Quantised Anomalous Hall Effect (QAHE) was observed for the first time in a magnetically doped topological insulator below 50 millikelvin in 2013. Similar to superconductivity, this effect allows lossless charge transport within thin edge channels of the samples. Meanwhile, it has been achieved to increase the maximum temperature at which the effect can be observed up to about 1 Kelvin.

However, based on theoretical considerations, the QAHE should occur at much higher temperatures. So it is a mystery as to why this does not happen. One critical parameter is known as the magnetic energy gap of the sample, but no one has ever measured it before. The larger this gap, the more stable the effect should be towards the influence of temperature.

Breakthrough at BESSY II

An international team headed by HZB physicist Prof. Dr. Oliver Rader and Prof. Dr. Gunther Springholz from the University of Linz has achieved a breakthrough. By photoelectron spectroscopy with synchrotron radiation of BESSY II they have been able to measure the energy gap in such a sample for the first time. To accomplish this, the equipment named ARPES1cube was used to reach extremely low temperatures as well as the new spin-resolving capability of the Russian-German Laboratory at BESSY II. Surprisingly, the gap was actually five times larger than theoretically predicted.

Self organised superstructure

The scientists also found a simple reason for this result: “We now know that manganese doping does not happen in a disordered manner. On the contrary, it causes stratification known as a superstructure in the material – layers much like a puff pastry”, explains Springholz. “By adding a few per cent of manganese, alternating units of seven and five layers are created. This causes the manganese to be preferentially contained within the seven-layer units and thus can generate the energy gap much more effectively.”

Rader says in retrospect that researchers' imaginations in using dopants has not extended far enough to date. They used trivalent elements such as chromium and vanadium that have magnetic characteristics to substitute for the bismuth in bismuth telluride (Bi2Te3), with the dopant atoms in a disordered state. The reason for this seemed very convincing: trivalent magnetic elements contribute three electrons to chemical bonds and their chemical valence leads these elements to the bismuth sites. With manganese, the situation is different. Since manganese is bivalent, it does not really fit well in the bismuth sites. That is apparently why the system becomes radically restructured and creates a new double layer of atoms in which manganese can be bivalently incorporated. “In this way, a structure is created – in a self-organized way - in which manganese can produce the large magnetic energy gap”, explains Rader.

Outlook quantum computing

If these self-organisation phenomena are exploited in specific ways, then completely new configurations can emerge for magnetic topological materials, according to Springholz. In principle, the gap that has now been measured is already so large that it should enable construction of a near-room-temperature QAHE from appropriate components. However, other parameters still need to be improved. A magnetic topological insulator like this in combination with an ordinary superconductor could also permit the realisation of a quantum processing unit (Qbit) for a quantum computer.

Nature (2019): Large magnetic gap at the Dirac point in Bi2Te3/MnBi2Te4 heterostructures. E. D. L. Rienks, S. Wimmer, J. Sánchez-Barriga, O. Caha, P. S. Mandal, J. Růžička, A. Ney, H. Steiner, V. V. Volobuev, H. Groiss, M. Albu, G. Kothleitner, J. Michalička, S. A. Khan, J. Minár, H. Ebert, G. Bauer, F. Freyse, A. Varykhalov, O. Rader & G. Springholz

DOI: 10.1038/s41586-019-1826-7

arö

  • Copy link

You might also be interested in

  • Battery research with the HZB X-ray microscope
    Science Highlight
    18.11.2024
    Battery research with the HZB X-ray microscope
    New cathode materials are being developed to further increase the capacity of lithium batteries. Multilayer lithium-rich transition metal oxides (LRTMOs) offer particularly high energy density. However, their capacity decreases with each charging cycle due to structural and chemical changes. Using X-ray methods at BESSY II, teams from several Chinese research institutions have now investigated these changes for the first time with highest precision: at the unique X-ray microscope, they were able to observe morphological and structural developments on the nanometre scale and also clarify chemical changes.
  • BESSY II: New procedure for better thermoplastics
    Science Highlight
    04.11.2024
    BESSY II: New procedure for better thermoplastics
    Bio-based thermoplastics are produced from renewable organic materials and can be recycled after use. Their resilience can be improved by blending bio-based thermoplastics with other thermoplastics. However, the interface between the materials in these blends sometimes requires enhancement to achieve optimal properties. A team from the Eindhoven University of Technology in the Netherlands has now investigated at BESSY II how a new process enables thermoplastic blends with a high interfacial strength to be made from two base materials: Images taken at the new nano station of the IRIS beamline showed that nanocrystalline layers form during the process, which increase material performance.
  • Hydrogen: Breakthrough in alkaline membrane electrolysers
    Science Highlight
    28.10.2024
    Hydrogen: Breakthrough in alkaline membrane electrolysers
    A team from the Technical University of Berlin, HZB, IMTEK (University of Freiburg) and Siemens Energy has developed a highly efficient alkaline membrane electrolyser that approaches the performance of established PEM electrolysers. What makes this achievement remarkable is the use of inexpensive nickel compounds for the anode catalyst, replacing costly and rare iridium. At BESSY II, the team was able to elucidate the catalytic processes in detail using operando measurements, and a theory team (USA, Singapore) provided a consistent molecular description. In Freiburg, prototype cells were built using a new coating process and tested in operation. The results have been published in the prestigious journal Nature Catalysis.