Konstanzer Physiker steuern Ströme zehntausendmal schneller als Hochgeschwindigkeits-Elektronik

Single electrons at top speed

Konstanz physicists control currents ten thousand times faster than high-speed electronics

At the University of Konstanz, the Chair for Ultrafast Phenomena and Photonics succeeded in controlling the movement of single electrons on attosecond timescales. One attosecond is the billionth part of a billionth second. The electric field of ultrashort light pulses in this process determines how the electrons are being transported between two nanoelectrodes. The long-term goal is to optically control the current flow in new types of devices, and thus much faster than possible with current semiconductor technology. The results were pre-published in the online issue of the expert journal Nature Photonics on 19 September 2016.

Light is electromagnetic radiation whose electric and magnetic field oscillates with an extremely high frequency in the tera- and petahertz range – that is a trillion or thousand trillion oscillations respectively per second. In the successful experiment in Konstanz, extremely short light pulses spanning only a single oscillation cycle are focused on two electrodes, two metallic pathways pointing at each other without actually touching. The gap between the two is only eight nanometres wide. Using ultrashort light pulses, the Konstanz physicists managed the following: the single electrons race from one electrode to the other over the free-space gap. The metallic nanostructures were produced with the help of electron beam lithography, a high-tech process to create nano-structures. The resolution of the structures the researchers have achieved is at the limit set by this technology.

The ultrashort optical pulses have a duration of only one cycle of light. In this case it is relevant whether the strongest half-oscillation of the field is positive or negative. This fact can be used to change the direction the electrons are moving in. Today it is possible to control electric circuits with transistors nearly in the terahertz range. The idea underlying the technology used by the team around Dr Daniele Brida, head of the junior research group, and Professor Alfred Leitenstorfer is that light makes it possible to switch electrons ten thousand times faster – on a time scale of around one hundred attoseconds.

The Konstanz physicists developed and constructed the control instrument for the experiments, an extremely sophisticated laser technology, themselves. This system can create the extremely short pulses with a duration of only one light oscillation. Moreover, the researchers can exactly control the chronological sequence of the electric field of this light pulse. As a consequence, this allows to control whether the electron moves from the right to the left, or the other way round.

Original Publication:
Tobias Rybka, Markus Ludwig, Michael Schmalz, Vanessa Knittel, Daniele Brida and Alfred Leitenstorfer: Sub-cycle optical phase control of nanotunnelling in the  single-electron regime. Nature Photonics. DOI: 10.1038/NPHOTON.2016.174

The project is being funded through numerous programmes: Collaborative Research Centre (SFB) 767, the Emmy Noether Programme of the German Research Foundation (DFG), the Advanced Grant of the European Research Council (ERC), the elite programme of the Baden-Württemberg Foundation and the “Marie Curie Carrier Integration Grant” (CIG) of the 7th Framework Programmes for Research and Technological Development of the European Commission.