Trapping of single ultracold atoms is an important tool for applications ranging from quantum computation and communication to sensing. However, most experimental setups, while very precise and versatile, can only be operated in specialized laboratory environments due to their large size, complexity and high cost. Here, we introduce a new trapping concept for ultracold atoms in optical tweezers based on micrometer-scale lenses that are 3D printed onto the tip of standard optical fibers. The unique properties of these lenses make them suitable for both trapping individual atoms and capturing their fluorescence with high efficiency. In an exploratory experiment, we have established the vacuum compatibility and robustness of the structures, and successfully formed a magneto-optical trap for ultracold atoms in their immediate vicinity. This makes them promising components for portable atomic quantum devices.
%0 Journal Article
%1 Ruchka_2022
%A Ruchka, Pavel
%A Hammer, Sina
%A Rockenhäuser, Marian
%A Albrecht, Ralf
%A Drozella, Johannes
%A Thiele, Simon
%A Giessen, Harald
%A Langen, Tim
%D 2022
%I IOP Publishing
%J Quantum Science and Technology
%K ColdMolecules myown pi5
%N 4
%P 045011
%R 10.1088/2058-9565/ac796c
%T Microscopic 3D printed optical tweezers for atomic quantum technology
%U https://doi.org/10.1088/2058-9565/ac796c
%V 7
%X Trapping of single ultracold atoms is an important tool for applications ranging from quantum computation and communication to sensing. However, most experimental setups, while very precise and versatile, can only be operated in specialized laboratory environments due to their large size, complexity and high cost. Here, we introduce a new trapping concept for ultracold atoms in optical tweezers based on micrometer-scale lenses that are 3D printed onto the tip of standard optical fibers. The unique properties of these lenses make them suitable for both trapping individual atoms and capturing their fluorescence with high efficiency. In an exploratory experiment, we have established the vacuum compatibility and robustness of the structures, and successfully formed a magneto-optical trap for ultracold atoms in their immediate vicinity. This makes them promising components for portable atomic quantum devices.
@article{Ruchka_2022,
abstract = {Trapping of single ultracold atoms is an important tool for applications ranging from quantum computation and communication to sensing. However, most experimental setups, while very precise and versatile, can only be operated in specialized laboratory environments due to their large size, complexity and high cost. Here, we introduce a new trapping concept for ultracold atoms in optical tweezers based on micrometer-scale lenses that are 3D printed onto the tip of standard optical fibers. The unique properties of these lenses make them suitable for both trapping individual atoms and capturing their fluorescence with high efficiency. In an exploratory experiment, we have established the vacuum compatibility and robustness of the structures, and successfully formed a magneto-optical trap for ultracold atoms in their immediate vicinity. This makes them promising components for portable atomic quantum devices.},
added-at = {2022-09-19T09:22:23.000+0200},
author = {Ruchka, Pavel and Hammer, Sina and Rockenhäuser, Marian and Albrecht, Ralf and Drozella, Johannes and Thiele, Simon and Giessen, Harald and Langen, Tim},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2bec9252ce0fc605d7ed982514842e90a/pi5},
doi = {10.1088/2058-9565/ac796c},
interhash = {9c353080c3a53f97000f3c45a0c425c3},
intrahash = {bec9252ce0fc605d7ed982514842e90a},
journal = {Quantum Science and Technology},
keywords = {ColdMolecules myown pi5},
month = jul,
number = 4,
pages = 045011,
publisher = {{IOP} Publishing},
timestamp = {2022-09-19T07:22:23.000+0200},
title = {Microscopic 3D printed optical tweezers for atomic quantum technology},
url = {https://doi.org/10.1088/2058-9565/ac796c},
volume = 7,
year = 2022
}