ESA Pharao space clock delivered to ISS - Video

ESA has welcomed the arrival of Pharao, an important part of ESA's atomic clock experiment that will be attached to the International Space Station in 2016.

Delivered by France's CNES space agency, Pharao is accurate to a second in 300 million years, which will allow scientists to test fundamental theories proposed by Albert Einstein with a precision that is impossible in laboratories on Earth.

Time is linked to gravity and, for example, passes faster at the top of Mount Everest than at sea level.

These effects have been proved in experiments on Earth but the Atomic Clock Ensemble in Space, ACES, will make more precise measurements as it flies 400 km high on humanity's weightless laboratory.

Comparing clocks under different gravity levels allows researchers to test Einstein's theories on space-time and other theories in fundamental physics.

To achieve its accurate timekeeping, the Pharao space clock uses lasers to cool caesium atoms down to -273 C, close to absolute zero.

Internet of clocks
Accurate timekeeping is vital for pinpointing our location, secure banking and fundamental science, but it is not easy to compare data from the many atomic clocks on Earth.

ACES is more than just one clock in space. Pharao will be accompanied by the Space Hydrogen Maser, which uses a different technique to keep track of time.

This clock uses hydrogen atoms as a frequency reference and offers better stability but for a shorter time.

By coupling the two clocks, ACES will provide the scientists with a unique, highly stable time reference in space.

The project will link together atomic clocks in Europe, USA, Japan and Australia with their space counterparts via microwave and optical links to create an 'internet of clocks' and to deliver precise timekeeping.

Connecting all these clocks is a significant part of ACES, with France's Cadmos User Support and Operations Centre taking responsibility for operating the instruments on the Station.

ESA astronaut Thomas Pesquet will be on the orbital outpost when ACES arrives in 2016. Using the Station's robotic arm, the 375 kg payload will be installed on a platform outside Europe's Columbus space laboratory.

UK Space Community benefits from £4.75m in Infrastructure Investment

The UK Space Agency will be channeling the new investment into three cutting-edge projects, including £3 million for a computing infrastructure at the International Space Innovation Centre for processing Earth observation data and making it more accessible for the UK space sector.

The three projects will rely on advances in computing, timing and data-handling to provide added benefits for industry and academia.

Centre for Climate Monitoring and Evaluation from Space (CEMS)
The CEMS at the International Space Innovation Centre will provide multi-sensor processing and a whole range of other tools and facilities for access, manipulation, visualisation and exploitation of data at realistic costs for companies (including SMEs).

UK Gaia Mission Data Processing and Analysis Centre (DPAC)
The University of Cambridge is receiving £0.75 million for a high performance computing system for the UK facility that will process the data from Gaia – Europe’s mission to examine the Milky Way in unprecedented 3-D detail.

The new computing system for the DPAC will support the effective use of mission data across the UK and beyond, including high bandwidth links to the data visualisation facilities at ISIC, Harwell.

Acquire and Exploit the Highest Quality Timing Data from Space (ACES)
Subject to approval by ESA and its Member States, £1M will be used to install a space-to-ground link from the planned ACES atomic clock system aboard the International Space Station to the National Physical Laboratory in Teddington, thus allowing an ultra-precision space-based timing signal to be made available to the UK's leading centre of metrology.

The funding will also allow specialised hardware to be provided to distribute the signal to key research and application development users in the UK.

The new funding for these projects is part of the Government’s multi-million pound e-infrastructure investment to provide UK scientists and businesses with access to the most sophisticated technology, keeping them at the cutting-edge of research and development. Minister for Universities and Science David Willetts said:

“We should not think of infrastructure as just roads and railways – it’s also the networks and systems that underpin our world-leading science and research base.

This ambitious and forward-looking programme of investment will be vital for businesses and universities alike. It will improve research and manufacturing processes and reduce the time and money it takes to bring a product to market.

“This will drive growth and innovation across a whole range of sectors and ensure our leading institutions and companies are able to exploit the very latest technology.”

ESA Portal - PHARAO atomic clock agreement signed by ESA and CNES

PHARAO atomic clock agreement signed by ESA and CNES

15 December 2009



ESA Portal - PHARAO atomic clock agreement signed by ESA and CNES

PHARAO atomic clock agreement signed by ESA and CNES

15 December 2009
ESA PR 31-2009 Today at the Paris headquarters of the French space agency (CNES), Simonetta Di Pippo, ESA Director of Human Spaceflight, and Thierry Duquesne, CNES Director for Strategy, Programmes and International Relations, signed an agreement that paves the way for the launch of a high-accuracy atomic clock to be attached to the outside of the European Columbus laboratory onboard the International Space Station (ISS).

The PHARAO (Projet d’Horloge Atomique par Refroidissement d’Atomes en Orbite) atomic clock, which will be combined with another atomic clock, the Space Hydrogen Maser (SHM), to form ESA’s Atomic Clock Ensemble in Space (ACES), will have an accuracy of 1x10^-16, corresponding to a time error of about one second over 300 million years.

This new generation of atomic clocks in space will be instrumental in enabling accurate testing of Einstein’s theory of general relativity. In addition, it will contribute to the accuracy and long-term stability of global timescales, e.g. International Atomic Time (TAI) and Coordinated Universal Time (UTC), and also help in the development of applications in the field of geodesy, and support applications involving remote sensing via the GNSS network.