Please type a search term (at least two characters)
The next generation of atomic clocks will support the growing industry need for accurate time
Atomic clocks form the basis of international time keeping, providing highly accurate time to a wide range of sectors around the world. The next generation of atomic clocks are based on optical frequencies using laser-cooled trapped ions.
European Metrology Programme for Innovation and Research (EMPIR) project Coulomb Crystals for Clocks (17FUN07, CC4C) is working to investigate laser-cooled trapped ions for optical clocks, examining the characteristics of multi-ion sources. It will also implement an advanced form of laser cooling, and develop transportable equipment to enable experiments to be carried out at nuclear physics and optical measurement laboratories. By supporting the reliability and precision of trapped ion optical clocks, this project will help to meet growing industry need for accurate time, provide an essential contribution to the revised International System of Units (SI unit) system, and open new perspectives for fundamental research with novel types of clocks.
The work of this project has featured in a number of high-profile initiatives, including journal articles, seminars and newspaper articles.
The work of the project consortium has resulted in publications in some high-profile journals:
- Coherent laser spectroscopy of highly charged ions using quantum logic published in Nature journal
- Measurement of the 229Th Isomer Energy with a Magnetic Microcalorimeter published in Physics Review Letters. This journal article triggered a series of media coverage and press releases including in APS Physics Viewpoint, Pro-Physik.de, Physics.org, Physics World.
- Electronic bridge excitation in highly charged Th-229 ions published in Physics Review Letters.
A virtual series of seminars was set up by the precision physics and quantum information community during the COVID-19 shutdown. Seminar on Precision Physics and Fundamental Symmetries has been attended by around 300 participants, and work from this project was presented in two talks:
- Trapped-ion optical clocks and tests of the equivalence principle
- Quantum Logic Spectroscopy of Highly Charged Ions for Optical Clocks and Tests of Fundamental Physics
The largest newspaper in Finland, Helsingin Sanomat, featured a 2-page article in July 2019 on the Finnish timescale showcases the optical trapped-ion clocks developed at VTT Mikes, Finland’s centre for measurement science.
Project Coordinator Ekkehard Peik from PTB said
‘This project provides us with a better understanding of the performance of this new generation of atomic clocks with trapped ions, and it opens some new perspectives for fundamental research, for example by bringing nuclear spectroscopy into the realm of precision frequency measurements. Several experiments are ongoing that have been designed for the project, taking data on the structure of two-species Coulomb crystals and on collision processes between the trapped ions and neutral background gases. Some of the results will likely be of relevance also for the rapidly expanding field of quantum computing with trapped ions’.
This EMPIR project is co-funded by the European Union's Horizon 2020 research and innovation programme and the EMPIR Participating States.
Want to hear more about EURAMET?
Sign up for EURAMET newsletters and other information
Follow us on LinkedIn and Twitter
EMPIR project contributes to the world’s first international standard in small magnetic measurements and produces guides and software to ensure compli... more
EMPIR project brings measurement traceability to additively manufactured medical implants that have the potential to revolutionise medicine more
Registration is open for the EURAMET Online Workshop: 2021 Call for Small Collaborative Projects (SCPs) more
The next generation of atomic clocks will support the growing industry need for accurate time more
This new open access online course has been created as part of an EMPIR project on advanced photovoltaic energy rating more