Fakultät für Physik und Astronomie

Physikalisches Kolloquium

Freitag, 16. Januar 2026 17:00 Uhr Unveiling the early stages of planet formation

Dr. Myriam Benisty, Max-Planck-Institut für Astronomie, Heidelberg Unveiling the early stages of planet formation Dr. Myriam Benisty Max-Planck-Institut für Astronomie, Heidelberg Recent observations have revealed a surprising diversity in planetary systems, but the processes that shape them are still not fully understood. Key questions remain about how and when planets form, how they interact with their surrounding environment - the protoplanetary disk, birthplace of planets - and how these interactions affect both the planets and the disk. Protoplanetary disks evolve and dissipate as planets form, implying strong feedback between disk dynamics and planet formation. These interactions leave observable signatures in the disk structure, which are now routinely detected with high-resolution telescopes. In this talk, I will introduce the major open questions in planet formation and present recent observational results that shed light on the processes that lead to the formation of planets.

Teilchenkolloquium

No tests of Locality via Bell’s Inequality nor of Entanglement at Colliders

Prof. Dr. Herbert Dreiner, Universität Bonn Testing for Locality via Bell’s Inequality or for Entanglement versus Non-Entanglement at Colliders? Dr. Herbert Dreiner Universität Bonn The question of non-locality and entanglement of QM has been a long-running and intriguing mystery. There have been successful experimental tests with pairs of photons in the eV energy range, for which the Nobel prize was awarded a few years ago. More recently there has been an increased interest in possible tests at colliders, ie at high energies and involving fermions. We argue that it is not possible to test for locality via Bell’s inequality at colliders, as one only measures commuting observables. We similarly argue that it is not possible to test for spin entanglement versus non-entanglement, as one always must invoke QM when translating the observed angular correlation of momenta to the underlying desired spin correlation. In each case we give several explicit examples.

Astronomisches Kolloquium

Dienstag, 13. Januar 2026 16:30 Uhr Exploring the Universe with high-energy gamma rays using H.E.S.S.

Lars Mohrmann, MPIK The High Energy Stereoscopic System (H.E.S.S.) is an array of imaging atmospheric Cherenkov telescopes (IACTs) that has been used to observe the sky in TeV gamma rays since 2004. Thanks to its unique location in the Southern Hemisphere and several upgrades to the system, the experiment continues to enable cutting-edge astrophysics despite its age. In my talk I will showcase the astrophysics that can be probed with IACTs, focusing on recent scientific highlights from H.E.S.S.

Zentrum für Quantendynamik Kolloquium

Mittwoch, 21. Januar 2026 16:30 Uhr Creating and Exploring Bose-Einstein Condensates of Dipolar Molecules

Prof. Sebastian Will, Department of Physics, Columbia University of New York Creating and Exploring Bose-Einstein Condensates of Dipolar Molecules Sebastian Will, Columbia University, Department of Physics, New York, NY, USA Recently, we have realized the first BEC of dipolar molecules [1]. We evaporatively cool a gas of sodium-cesium molecules to below 10 nanokelvin, deep in the quantum degenerate regime. The BECs live for several seconds. This dramatic improvement over previous molecular cooling efforts is enabled by collisional shielding via microwave dressing, suppressing inelastic losses by four orders of magnitude [2]. Microwave dressing also provides an exceptional level of tunability of dipole-dipole interactions, opening the door to novel phases of matter in molecular quantum liquids. Most recently, we have observed self-bound droplets in a gas of strongly dipolar molecules [3]. In this talk, I will describe our experimental approach, discuss recent results, and give an outlook on novel opportunities enabled by molecular BECs for many-body quantum physics, quantum simulation, and quantum computing. I will also briefly highlight our broader efforts in quantum, including recent advances on single atom trapping in metasurface optical tweezer arrays [4]. Figure: Formation of self-bound droplets in a BEC of dipolar NaCs molecules References: [1] Bigagli, Yuan, Zhang, et al., Observation of Bose-Einstein condensation of dipolar molecules, Nature 631, 289-293 (2024) [2] Yuan, Zhang, et al., Extreme loss suppression and wide tunability of dipolar interactions in an ultracold molecular gas, arXiv:2505.08773 (2025) [3] Zhang, Yuan, et al., Observation of self-bound droplets of ultracold dipolar molecules, arXiv:2507.15208 (2025) [4] Holman, Xu, et al., Trapping of single atoms in metasurface optical tweezer arrays, arXiv:2411.05321 (2024) (in print) Bio: Sebastian Will is an Associate Professor of Physics at Columbia University. His research focuses on ultracold atoms and molecules for applications in fundamental science, quantum simulation, quantum computing, and quantum networking. He is a recipient of the Columbia RISE Award, the NSF Career Award, and a Sloan Fellowship. His research is supported by the NSF, AFOSR, ARO, ONR, DOE, and the Gordon and Betty Moore Foundation.

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