ERBIUM LAB

Erbium has very special properties that make it unique: a remarkably strong magnetic moment, many valence electrons, clock transitions, and an exceptionally rich internal atomic structure. In the ERBIUM LAB we bring all these properties in the quantum regime together to study strongly dipolar gases both in the continuum and in optical lattices

Our experiments have focused on studying the impact of dipolar interactions in various scenarios. In bulk systems, we have provided the first evidence of the many-body nature of these interactions and of their interplay with the Pauli exclusion principle, through the observation of the deformation of the Fermi surface [1]. At the microscopic scale, we focused on the intriguing chaotic scattering behavior of Er atoms, arising from the interplay between the orbital and magnetic anisotropies of the particles [2]. In lattices, we achieved a significant milestone by being the first to realize the extended Bose-Hubbard model, revealing the modified transition from a superfluid to a Mott insulator driven by dipolar interactions [3].

These explorations have led to an in-depth study of supersolidity, made possible by two fundamental experimental achievements. The observation of the transition from the ground state of an Er Bose-Einstein condensate to a self-sustaining macro-droplet state, demonstrated the unexpected stabilizing effect of quantum fluctuations [4]. Furthermore, the pioneering observation of roton-like quasiparticles revealed the possibility of inducing crystallization of the system via dipolar interactions [5]. These efforts have culminated in the long-awaited production of a long-lived supersolid, characterized by complex behavior reminiscent of both a crystal and a superfluid, as part of a collaboration between the Er-Dy and ERBIUM teams and our theoretical collaborators at IQOQI [6].

Remarkably, Er also features a large spin, offering many opportunities for quantum simulation. The groundwork has been laid with the implementation of a long-range Heisenberg XXZ model in a fermion lattice and the precise control of spin-exchange dynamics [7]. These efforts have been further enhanced by the recent demonstration of the manipulation of a narrow inner-shell orbital transition at 1299-nm [8], enabling exhaustive control over the spin composition of the system. This convergence of advancements holds the potential for the realization of a new generation of synthetic quantum magnets in clean, isolated, and fully controllable environments. The technological applications of such systems span a wide range, from precision sensing to quantum information processing.

[1] For a general overview of Fermi surface deformation, see our writeup. This work was published in Science, and the preprint can be found on the arXiv.

[2] For a general overview of this work on quantum chaos, see the following article on ScienceDaily. This work was published in Nature, and the preprint can be found on the arXiv.

[3] For a general overview of this work on the Bose-Hubbard model, see the press release by UIBK. This work was published in Science, and the preprint can be found on the arXiv.

[4] For a general overview of the BEC macrodroplet, see our writeup and the article by Physics Magazine. This work was published in Physical Review X, and the preprint can be found on the arXiv.

[5] For a general overview of the roton in Erbium, see our writeup, the press release by UIBK and . This work was published in Nature, and the preprint can be found on the arXiv.

[6] For a general overview of the supersolid phase, see our writeup and the press release by UIBK, and the article by Physics Magazine. This work was published in Physical Review X, and the preprint can be found on the arXiv.

[7] For a general overview of these lattice-confined dipolar fermions, see our writeup. This work was published in Physical Review Research, and the preprint can be found on the arXiv.

[8] For a general overview of this narrow inner-shell orbital transition, see our writeup. This work was published in Physical Review Research, and the preprint can be found on the arXiv.

A full list of the ERBIUM Lab publications can be found here.

Interested in joining us? Check out our open positions here.

Lab news

Forschungsgruppe-Taskforce meeting in Maria Waldrast

On 3rd and 4th of November 2016 the Erbium team from Innsbruck, the Dysprosium team of Tilman Pfau from Stuttgart and theorists from Luis Santos group from Hannover gathered in Maria Waldrast for an informal meeting, to discuss future prospects of ultracold quantum gases of lanthanide atoms.

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Claudia and Gabriele join our group

Originally from Caserta, Claudia Politi and Gabriele Natale are master students of the University of Pisa and now joined us in Innsbruck for the next full year. Welcome! 🙂

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The Long-range workshop in Ercolano

This year, from 6.-9. September 2016, the third edition of the workshop on 'Long-range interactions in the ultracold', took place in Ercolano (Naples, IT). Since the event was organised by Francesca (together with Antoine Browaeys and Robert Löw), the whole team joined in for the event, rented a Minibus and

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Short video about the Erbium lab

Back in 2009, the Erbium experiment was starting with funding from the Austrian academy of science (through an FWF START-price) and an ERC Starting grant. Since the START price is now expired, the FWF send a Camera team to our lab for a short video.

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Jan Hendrik Becher joins our group

MariaWaldrast_groupPic Jan will work with us for a full year on the Erbium experiment as part of his PhD at the University of Heidelberg. After that, he continues his studies in the group of Selim Jochim. Welcome Jan to our group! 🙂

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Giulia joins the ERBIUM-Team

Giulia Faraoni is currently doing her PhD degree in Florence (Italy) at the LENS institute. To gather additional experience and skills, she will work with us for a full year on the Erbium experiment on dipolar quantum droplets. Welcome to our group!

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