Detraction-free light-matter interaction

Detraction-free light-matter interaction
Sven Scholz (left) and Arne Ludwig are experts for generating quantum dots in semiconductors. Credit: RUB, Kramer

An efficient light-matter interface might constitute the foundation of quantum communication. However, certain structures that are formed during the growth process interfere with the signal.

Certain semiconductor structures, so-called , might constitute the foundation of quantum communication. They are an efficient interface between matter and light, with photons (light particles) emitted by the quantum dots transporting information across large distances. However, structures form by default during the manufacture of quantum dots that interfere with communication. Researchers at the University of Basel, Ruhr-Universität Bochum, and Forschungszentrum Jülich have now successfully eliminated these interferences. They've published their report in the journal Communications Physics from 9 August 2019.

Light particles capable of transporting information across large distances

Quantum dots can be realized in semiconductors if researchers lock an electron and an electron hole—i.e. a positive charge at a position where an electron should exist—in a constricted space. Together, electron and electron hole form an excited state. When they recombine, the disappears and a photon is generated. "That might be usable as information carrier in quantum communication across large distances," says Dr. Arne Ludwig from the Chair for Applied Solid State Physics in Bochum.

The quantum dots manufactured in Bochum are generated in the semiconductor material indium arsenide. The researchers grow the material on a gallium arsenide substrate. In the process, a smooth indium arsenide layer forms at a thickness of a mere one and a half —the so-called wetting layer. Subsequently, the researchers generate small islands with a diameter of 30 nanometers and a height of a few nanometers. These are the quantum dots.

Interfering photons from wetting layer

The wetting layer that has to be deposited in the first step causes problems, because it, too, contains excited electron hole states that decay and may release photons. In the wetting layer, these states decay even more easily than in the quantum dots. The photons emitted in the process can't be used in quantum communication, however; rather, they generate a static noise in the system.

"The wetting layer covers the entire surface while the quantum dots only cover a thousandth of the semiconductor chip, which is why the interfering light is approximately a thousand times stronger than the light emitted by the quantum dots," explains Andreas Wieck, Head of the Chair for Applied Solid State Physics in Bochum. "The wetting layer radiates photons at a slightly higher frequency and at a much higher intensity than the quantum dots. It's as if the quantum dots emitted the chamber pitch A, whereas the wetting layer emitted an B that was a thousand times louder."

Additional layer eliminates interferences

"We have been able to ignore those interferences by exciting only the required energy states," says Matthias Löbl from the University of Basel. "However, if quantum dots are to be used as information units for quantum applications, it might be ideal to charge them with more electrons. But in that case, the in the wetting layer would be likewise excited," adds Arne Ludwig.

The research team has now eliminated this interference by adding an aluminum arsenide layer grown above the quantum dots in the wetting layer. The energy states in the wetting are thus removed, which, in turn, makes it less likely for electrons and electron holes to recombine and emit photons.

More information: Matthias C. Löbl et al. Excitons in InGaAs quantum dots without electron wetting layer states, Communications Physics (2019). DOI: 10.1038/s42005-019-0194-9

Journal information: Communications Physics

Provided by Ruhr-Universität Bochum

Citation: Detraction-free light-matter interaction (2019, August 23) retrieved 9 December 2022 from
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