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A: Fachverband Atomphysik

A 3: Bosonic Quantum Gases I (joint session Q/A)

A 3.6: Vortrag

Montag, 11. März 2024, 12:15–12:30, Aula

Ramsauer Townsend effect and Bragg scattering in an analogue cosmology experiment — •Marius Sparn¹, Elinor Kath¹, Nikolas Liebster¹, Christian F. Schmidt², Álvaro Parra-López³, Mireia Tolosa-Simeón⁴, Helmut Strobel¹, Stefan Floerchinger², and Markus K. Oberthaler¹ — ¹Kirchhoff-Institut für Physik, Universität Heidelberg — ²Theoretisch-Physikalisches Institut, Friedrich-Schiller-Universität Jena — ³Departamento de Física Teórica and IPARCOS, Universidad Complutense de Madrid — ⁴Institut für Theoretische Physik III, Ruhr-Universität Bochum

Cosmological particle production arises when a quantum field is subject to an expanding metric. This phenomenon heavily depends on the details of the cosmological history. Strikingly, this relativistic, time-dependent process can be mapped to a scattering problem, described by a non-relativistic stationary Schroedinger-equation, wherein the scattering potential is determined by the specific form of the expansion. Here we present results from an analogue cosmology experiment with a two-dimensional Bose-Einstein condensate, simulating a scalar quantum field in a FLRW-spacetime [1]. We use the scattering framework to investigate instructive examples, such as a box potential, corresponding to a singular expanding space-time as well as a periodic potential, corresponding to a periodic expansion and contraction. The measured spectra of produced particles reveal features analogue to resonant forward (Ramsauer-Townsend) scattering and Bragg scattering, respectively. [1] Viermann, C. et al. Nature 611, 260-264 (2022)

Keywords: Analogue Gravity; Bose-Einstein Condensates; Quantum Simulation; Ultracold Atoms; Cosmology