Joint research group for quantum computing and simulation
© Freie Universität Berlin
Freie Universität Berlin and Helmholtz-Zentrum Berlin (HZB) are now strengthening their cooperation in the field of quantum computing with a new research group. Quantum materials exhibit very interesting properties, which researchers want to use to make data processing significantly faster and more efficient than is currently possible. They can study these materials excellently at synchrotron radiation sources such as BESSY II. It has proven especially promising to predict the material properties in quantum simulations before running the experiments. Taking this approach allows such experiments to be conducted more targetedly.
“Simulating how highly complex material properties emerge”
Jens Eisert is a professor of physics at Freie Universität Berlin and the head of the joint research group. He is an internationally renowned expert for quantum many-body theory, quantum information theory, and quantum optics.
How did this collaboration with HZB come about?
Jens Eisert: Our collaboration arose out of promising and inspiring discussions with Bella Lake, a physicist at Helmholtz-Zentrum Berlin. We had been working on problems of strongly correlated systems in the laboratory, which were difficult to solve with conventional methods. At that stage, the methods of tensor networks were able to deliver the first insights for those systems, but not a comprehensive picture. It took a lot of hard work before we could develop methods powerful enough to model and simulate correlated systems out of the laboratory. From this cooperation, we recognised the major potential that existed in stronger collaboration.
What other points of contact do you see between your research and the topics addressed at HZB?
There are many opportunities. The initial discussions with Bella Lake have culminated in a research programme that offers many possibilities – a genuinely comprehensive programme.To name a few, Johannes Reuther, Oliver Rader, Boris Naydenov, Annika Bande, and other researchers from HZB have announced their interest in collaborating. And indeed it makes sense, from a strategic point of view, to build up a combined initiative on quantum technologies in Berlin.
Are there already any concrete ideas for practical projects the research group can work on?
Definitely. There are many topics that we are already working on, or intend to tackle soon. As a concrete example, we are investigating how highly complex properties emerge out of simple interactions in quantum materials – and how they can be modelled. Together, we also want to delve deeper into questions of realistic quantum computers and quantum simulators. First, we will recruit two new researchers to tackle those questions. They will be working mainly at Freie Universität Berlin, but will maintain very close contact with HZB. I am very pleased about this collaboration because working directly with groups from HZB who also conduct experiments is very fruitful for theoretical physics.
- Disorder creates new properties in compound semiconductorsAn international research team has demonstrated that the intrinsic disorder of the compound semiconductor CuInSnS₄ can be exploited to influence its optical properties. While the atomic vibrations also sense the local disorder, their response is averaged over many different local environments and therefore appear isotropic, as expected for a cubic crystal. In contrast, the optical excitations, known as excitons, are much more sensitive to the local arrangement of atoms. Surprisingly, they show a direction-dependent optical response even though the average crystal structure is cubic. These findings shed new light on the relationship between disorder and material properties, opening up new options for targeted 'disorder engineering' in optoelectronic and photocatalytic devices.
- Superconducting TES array X-ray spectrometer goes into operation at BESSY IIEurope's first and only TES-spectrometer at a synchrotron source is now in operation at BESSY II, developed within a collaboration between the HZB, the MPI-CEC (Mühlheim-an-der-Ruhr, Germany) and the NIST (Boulder CO, USA). The photon detection efficiency of the new instrument exceeds that of wavelength-dispersive X-ray emission spectrometers by a factor of 100 to 1000. It will be used to investigate the electronic properties of atomically thin layers, nanostructures and highly diluted atomic and molecular samples. The team is looking forward to receiving exciting research proposals from the user community.
- A New Era in Catalysis: ASCEND Launch in Berlin, €30 Million in FundingOn 11 June 2026, the Helmholtz-Zentrum Berlin (HZB) in Adlershof hosted the launch of ASCEND (Accelerated Solutions for Catalysis using Emerging Nanotechnology and Digital Innovation). The event took place in the presence of the Minister of Research, Dorothee Bär, President of the Helmholtz Association, Prof. Dr. Martin Keller, and President of the Max Planck Society, Prof. Dr. Patrick Cramer. Bringing together leading partners from industry and research, ASCEND is supported by BMFTR with €30 million in funding and officially started on 1 April 2026. The initiative aims to accelerate the discovery of next-generation catalysts and enable more sustainable chemical processes.