46th Annual Meeting of the APS Division of Atomic, Molecular and Optical Physics
Volume 60, Number 7
Monday–Friday, June 8–12, 2015;
Columbus, Ohio
Session J2: Invited Session: Ion Spectroscopy for Tests of Fundamental Physics
2:00 PM–4:00 PM,
Wednesday, June 10, 2015
Room: Union ABC
Chair: Joseph Tan, National Institute of Standards and Technology, Gaithersburg
Abstract ID: BAPS.2015.DAMOP.J2.2
Abstract: J2.00002 : Coulomb crystallization of sympathetically cooled highly charged ions
2:30 PM–3:00 PM
Preview Abstract
Abstract
Author:
Jos\'e R. Crespo L\'opez-Urrutia
(Max Planck Institute for Nuclear Physics)
Wave functions of inner-shell electrons significantly overlap with the
nucleus, whereby enormously magnified relativistic, quantum electrodynamic
(QED) and nuclear size effects emerge. In highly charged ions (HCI), the
relative reduction of electronic correlations contributions improves the
visibility of these effects. This well known facts have driven research
efforts with HCI, yet the typically high temperatures at which these can be
prepared in the laboratory constitutes a serious hindrance for application
of laser spectroscopic methods. The solution for this, cooling HCI down to
crystallization has remained an elusive target for more than two decades. By
applying laser cooling to an ensemble of Be$^{+}$ ions, we build
Coulomb crystals that we use for stopping the motion of HCI and for cooling
them. HCI, in this case Ar$^{13+}$ ions are extracted from an
electron beam ion trap with an energy spread of a few 100's of eV, due to
the ion temperature within the trap. Carefully timed electric pulses in a
potential-gradient decelerate and bunch the HCI. We achieve Coulomb
crystallization of these HCI by re-trapping them in a cryogenic linear
radiofrequency trap where they are sympathetically cooled through Coulomb
interaction with the directly laser-cooled ensemble. Furthermore, we also
demonstrate cooling of a single Ar$^{13+}$ ion by a single
Be$^{+}$ ion, prerequisite for quantum logic spectroscopy with
potentially 10$^{-19}$ relative accuracy. The strongly suppressed
thermal motion of the embedded HCI offers novel possibilities for
investigation of questions related to the time variation of fundamental
constants, parity non-conservation effects, Lorentz invariance and quantum
electrodynamics. Achieving a seven orders-of-magnitude decrease in HCI
temperature, from the starting point at MK values in the ion source down to
the mK range within the Coulomb crystal eliminates the major obstacle for
HCI investigation with high precision laser spectroscopy and quantum
computation schemes.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2015.DAMOP.J2.2