Fabian Steinlechner Appointed as New Professor for Experimental Quantum Information

The Experimental Quantum Information professorship of Fabian Steinlechner is supported by the Carl-Zeiss-Stiftung within its Carl-Zeiss-Stiftung Center for Quantum Photonics (CZS Center QPhoton).
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Published: | By: Ira Winkler and Christian Helgert

New professorship supported by the Carl-Zeiss-Stiftung

Carl-Zeiss-Stiftung Logo

Picture: Carl-Zeiss-Stiftung.

The quantum expert Dr. Fabian Steinlechner received his PhD in 2015 from ICFO (Barcelona, Spain) where his doctoral research focused on the development of quantum light sources for applications in Space. As a postdoctoral fellow at the Institute for Quantum Optics and Quantum Information in Vienna, he contributed to the application of entangled photons in loophole-free tests of non-locality, quantum sensing, high-dimensional quantum information processing, and long-distance quantum communication in free-space and fiber links. In 2018, he established the Quantum Communication Technologies group at Fraunhofer IOF Jena. Since 2024, he is full professor at the Institute of Applied Physics.

The professorship is supported with 1.7 Mio EUR by the Carl-Zeiss-StiftungExternal link within its Carl-Zeiss-Stiftung Center for Quantum Photonics (CZS Center QPhoton)

Interview with Fabian Steinlechner

Dear Fabian, congratulations on your appointment! For those who don't know you yet, could you please give us a brief overview of your academic career?

"Thank you very much! I completed my degree in technical physics in Vienna in 2009, where I also wrote my diploma thesis under the supervision of Anton Zeilinger.  I then did my doctorate in the optoelectronics group at the ICFO in Barcelona under the supervision of Valerio Pruneri. My research topic was the development of quantum light sources for space applications. After my PhD in 2015, I returned to the Academy of Sciences in Vienna as a postdoctoral researcher to join the group of Rupert Ursin and worked on a series of experiments on quantum communication and fundamental aspects of quantum nonlocality. In 2018, I was appointed as a junior research group leader at Fraunhofer IOF Jena with my research program "Photonic Technologies for Quantum Communication". Thanks to the nice conditions in Jena and the rapid growth in application-oriented quantum photonics in Germany, the group has grown to 30 employees in just 5 years."

What have been the highlights of your scientific career so far?

"In my scientific career, I have had the privilege of working with leading experimental physicists, theorists and technologists who understand science, education and technology in very different ways. This has not only helped me in terms of content, but has also shaped my approach to research and ultimately my leadership style.

One highlight was certainly the opportunity to experience first-hand how Anton Zeilinger, Nobel Prize winnter in 2022, inspires innovation among his colleagues. During my diploma thesis, I was able to gain my first experience with entangled photons there and later, as a postdoc, I was involved in fundamental experiments on the non-locality of entangled particles. I also remember with pleasure the special locations where we ran experiments, such as on the Canary Islands doing quantum communication over a distance of 144 km between La Palma and Tenerife. At that time it was the longest distance bridged for such. These experiences had a special appeal, above all because we were able to make a further contribution to the experimental disproof of Einstein's concept of local realism and the validity of the predictions of quantum mechanics with a test of Bell's inequality.

Another highlight was my time at the ICFO in Barcelona, where I was able to make a large variety of contacts and learned a lot from my doctoral supervisor about the implementation of complex R&D with limited resources. During this time, I worked intensively on the challenges of quantum communication and the space feasibility of photonic quantum technology. This work later led me to Jena.

A key event for me was certainly my appointment as group leader at Fraunhofer IOF and the launch of the QuNET initiative immediately after my arrival in Jena. The aim of this initiative is to create the physical and technical basics for a quantum-safe government network in Germany. In a series of demonstrator experiments, my team was able to show the practicability of quantum entanglement for quantum communication in fiber and free-beam links."

What exactly does your work in experimental quantum information involve?

"My work is about generating and manipulating quantum states of light and making them usable for various applications. One focus is on the realization of quantum networks. We investigate the entanglement of photons over long distances and develop protocols based on this for secure communication. We are also working on the development of technologies for measurement technology and quantum computers."

How do you see the significance of your research for the future of information and communication technology?

"Quantum physics offers enormous potential for information and communication technology. By using quantum networks, we can transmit data with absolute safety and create new possibilities in distributed information processing. In addition, quantum computers have the potential to perform complex calculations much faster than conventional computers."

What are you most looking forward to in your role as a professor?

"I'm looking forward to helping to actively shape and support the solution of theoretical and technical problems. I now see myself primarily guiding my colleagues through their research projects, designing new experiments and passing on my knowledge. I would also love to be involved in the lab or on the computer.

I have learned that it is important to create space for ideas to be formed, to pursue interests and at the same time to promote and strengthen personal responsibility. This should also involve one's own colleagues, such that everyone benefits from each other: Experimental Quantum Information = Team Sport - only in a good team can everything flow.

My personal conviction is also that this interest is particularly useful and far-reaching if you think about the development of technologies beyond the doctorate and make the new findings accessible to everyone. "

How do you see the importance of experimental quantum information for future technologies and applications? And what potential impact could it have on society?

"I think that quantum information has a special place in society in many areas. On the one hand, it enables practical applications in the medium future, which I hope will become state-of-the-art solutions. Then this fascinating and initially unfamiliar technology will become part of everyday life for many people. When terms such as quantum entanglement and quantum superposition enter common language, new perspectives and completely different application possibilities will be opened up. We are currently only scratching the surface of what is possible.

However, such future perspectives should be approached with a realistic timeline and expectations. In addition to many conceptual challenges, quantum technology also places immense demands on the underlying technological basis - in order to gain new insights and carry out revolutionary experiments, numerous highly developed components are required. And this also shows very clearly how theory and experiment are intertwined: only when I can build the corresponding experimental setups and new experimental devices can I verify the theory - but for that I need the theory.

In order for fundamental progress to be translated into quantum applications with added value for society, close cooperation between different disciplines - e.g. computer science, materials science, engineering - is required in addition to the bridge between theory and experiment. I think that Jena offers particularly fertile ground due to the historically proven synergy between basic research and application. I hope to make a contribution in this field of tension between basic research and application.”

What advice or recommendation do you have for students who are interested in experimental quantum information as a field of research?

"Quantum technology is a very interdisciplinary field of research. Therefore, I can only give the following advice: Learn as much as you can about topics you need but in the first step not more than necessary. You should be broad enough for experimentation and research. You should follow your interests fully and only bring the idea of application into the game later. It is difficult to assess the possibilities for applications at the beginning of your research.

Another important point is that experiments today are so complex that they cannot be managed by a single person - open communication and respectful interaction as the basis for good teamwork are therefore just as essential."

Are there any current trends or developments in quantum information that you consider to be particularly promising?

"One promising trend in quantum information is research into quantum networks. This involves the entanglement of quantum states over long distances and the development of protocols for the secure transmission of quantum mechanical information. There are still many fundamental questions in this area, and I'm looking forward to further insights and surprises that await us in the future."

Thank you very much for the interview and good luck with your work here at the CZS QPhoton and at the Institute of Applied Physics!

Fabian Steinlechner, Prof. Dr
Head of Department
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Experimental Quantum Information
IOF, Room EG02/306
Albert-Einstein-Straße 7
07745 Jena Google Maps site planExternal link