{"id":21,"date":"2015-09-25T22:24:57","date_gmt":"2015-09-25T20:24:57","guid":{"rendered":"http:\/\/www.erbium.at\/FF\/?page_id=21"},"modified":"2025-08-13T12:08:11","modified_gmt":"2025-08-13T10:08:11","slug":"research","status":"publish","type":"page","link":"https:\/\/www.erbium.at\/FF\/research\/","title":{"rendered":"Research"},"content":{"rendered":"

Our research focuses on ultracold strongly magnetic Lanthanides for realizing dipolar quantum matter<\/strong>. Lanthanides are a novel and powerful resource for accessing quantum many- and few-body physics because of their extremely rich atomic level spectra and their highly anisotropic interaction potentials. Our goal is to study the fascinating effects emerging from the dipole-dipole interaction and the anisotropic short-range van der Waal interaction, working at the interface between condensed matter, atomic and molecular physics.<\/p>\n

We have three experimental apparatuses: the ERBIUM lab<\/a><\/strong> operates on Er atoms and produced the first Er Bose-Einstein condensate and degenerate Fermi gas; the Er-Dy lab<\/a><\/strong> creates Bose-Bose and Bose-Fermi quantum mixtures of Erbium and Dysprosium and studies dipolar mixture physics; the T-REQs lab<\/a><\/strong> studies Rydberg states of Er and the trapping of atoms arrays in optical tweezers for quantum simulation; and the Dy-Yt lab<\/a><\/strong>, currently under construction – this new experimental apparatus will be used to study many-body phases of highly-magnetic dysprosium and of mixtures with non-magnetic ytterbium. We also have a Theory division<\/a> <\/strong>within our group, who use state-of-the-art numerical and analytical techniques to understand the behaviour of ultracold dipolar atoms, and explore their potential for quantum simulation.<\/p>\n