Our group conducts experiments on the following topics: thermodynamics of light, as Bose-Einstein condensation of photons in microcavities, and the statistics and dynamics of photons in tailored potentials. We also investigate topology and quantum simulation with ultracold atomic gases.
We are always looking for Bachelor, Master, PhD students, and postdocs. For more information, see here.
Latest news
Since 01.04.2025 Arif is an Assistant Professor at IIT
Our former postdoc at the erbium experiment, Arif Warsi Laskar was appointed Assistant Professor at the department of physics at the Indian Institute of Technology Guwahati in the region Assam. In the research group "Quantum Optics and Quantum Technology" he will use his experience gained in Bonn, and will, among others, set up experiments in gold gases.
Julian Schmitt has been appointed full professor at the Ruprecht-Karls University of Heidelberg
Julian will join the Kirchhoff-Institute for Physics as of 1st of January 2025 and the team members and labs will join the new laboratories in the next months of 2025. At Heidelberg, his experimental research group “Optical Quantum Systems” (optiQS) will explore emergent phenomena in quantum fluids of light, topological photonics and physical computation using open light-matter systems.
Kiran's paper on the 1d-2D crossover is published
It is long known that the dimensionality of a system has great influence on the laws of physics. In one dimension, the Hohenberg-Mermin-Wagner theorem predicts that, under some constraints, long-range order cannot be established in one dimension, as thermal fluctuations drive the system to an unordered situation. But what happens when going from two to one dimension? We have studied this crossover together with colleagues from the RPTU Kaiserslautern-Landau in a quantum gas of light.
Photons condense into a ring-like ground state
Photons confined in a potential with tunnel-coupled minima in a ring shape can populate the hybridized states of that ring. The ground state in such a ring is the symmetric superposition of the eigenstates of the individual wells, a smeared-out ringlike state. Using cooling enabled by thermal contact to a dye solution, we were able to coll directly into this ground state, and verify the phase coherence of the superposition state. The results have been published in Physical Review Letters.
Our research
© H. Brammer/U Bonn
Erbium Experiment:
Topology with Ultracold Atoms
© AG Weitz
Rubidium Experiment:
Quantum Simulation
© U. Vogl / AG Weitz
Ultradense Gases: Laser Cooling & Spectroscopy
© AG Weitz
Spectroscopy of High Pressure Gases:
Novel Light Sources in the VUV
© T. Damm/U Bonn
Photon Bose-Einstein-Condensation: Statistical Physics
© C. Kurtscheid/U Bonn
