TY  - GEN
Y1  - 2020///
A1  - Stark, Julian Gunnar Josef
CY  - Heidelberg
ID  - heidok28742
AV  - public
UR  - https://archiv.ub.uni-heidelberg.de/volltextserver/28742/
TI  - An Ultralow-Noise Superconducting Radio-Frequency Ion Trap for Frequency Metrology with Highly Charged Ions
N2  - Highly charged ions (HCIs) are excellent candidates for next-generation frequency standards, as they feature a much-reduced susceptibility to external perturbations, and are
proposed to stringently test physics beyond the Standard Model of particle physics. These applications require spectroscopy of HCIs with an accuracy on the level of state-of-the-art trapped-ion frequency standards. In order to overcome the current limitations due to
motional frequency shifts, an efficient suppression of trap-induced heating rates is essential. To that end, a new cryogenic Paul trap experiment, CryPTEx-II, was developed and commissioned within this work. It consists of a novel superconducting ion trap uniquely combining a radio-frequency (rf) cavity and a Paul trap, and a low-vibration cryogenic supply to cool the trap to temperatures of 4.15 K while decoupling external vibrations.
The cavity features an electric quadrupole mode at 34.52 MHz with a quality factor of  ~2.3 x 10^5, which allows for stable confinement of ions in ultralow-noise rf potentials and is expected to result in strongly suppressed motional heating rates. Commissioning experiments comprised the operation of the cavity as a quadrupole mass filter to focus
HCIs through the cavity as well as the first trapping and laser cooling of 9Be+ ions. These constitute the successful proof-of-principle operation of this unique apparatus, which will be used for high-precision experiments with HCIs in the future.
ER  -