Trapping and cooling of single ions for frequency metrology and quantum optics experiments

0482630 - ÚPT 2018 RIV CZ eng C - Conference Paper (international conference)
Slodička, L. - Pham, Minh Tuan - Lešundák, Adam - Hucl, Václav - Čížek, Martin - Hrabina, Jan - Řeřucha, Šimon - Lazar, Josef - Obšil, P. - Filip, R. - Číp, Ondřej
Trapping and cooling of single ions for frequency metrology and quantum optics experiments.
Proceedings of the 15th International Seminar on Recent Trends in Charged Particle Optics and Surface Physics Instrumentation. Brno: Institute of Scientific Instruments CAS, 2016 - (Mika, F.), s. 68-69. ISBN 978-80-87441-17-6.
[International Seminar on Recent Trends in Charged Particle Optics and Surface Physics Instrumentation /15./. Skalský dvůr (CZ), 29.05.2016-03.06.2016]
R&D Projects: GA ČR GB14-36681G; GA MŠMT(CZ) LO1212; GA MŠMT ED0017/01/01
Institutional support: RVO:68081731
Keywords : quantum optics experiments * frequency metrology
OECD category: Optics (including laser optics and quantum optics)
http://www.trends.isibrno.cz/

Single trapped ions trapped in Paul traps correspond to ideal candidates for realization of extremely accurate optical atomic clocks and practical studies of the light–atom interactions and nonlinear mechanical dynamics. These systems benefit from both, the superb isolation of the ion from surrounding environment and excellent control of its external and internal
degrees of freedom, at the same time, which makes them exquisite platforms for experimental studies and applications of light matter interaction at its most fundamental level. The exceptional degree of control of single or few ion's state enabled in past decade number of major advancements in the applications from the fields of experimental quantum information
processing and frequency metrology, including recent realization of scalable Shor's
algorithm, fractional uncertainties of the frequency measurements close to 10-18 level, or simulations of complex quantum many-body effects. These results, together with the rapid advancements in the production of low-noise segmented micro-traps, promise prompt access to long-desired regimes of quantum optomechanics and further development and applications
of optical atomic clocks.
Permanent Link: http://hdl.handle.net/11104/0278051