The most advanced space weather radar in the world is to be built in the Arctic by an international partnership including the UK, thanks to new investment, in the region of £4 to £6m from NERC.
The EISCAT_3D radar will provide UK scientists with a cutting-edge tool to probe the upper atmosphere and near-Earth space, helping them understand the effects of space weather storms on technology, society and the environment.
The UK government has placed space weather on the National Risk Register, in recognition of the potential damage it can do to satellites, communications and power grids. Solar storms drive space weather, but one of the biggest challenges in space weather science is improving our understanding of how the Earth's magnetic field and atmosphere responds to this. EISCAT_3D will give scientists the means to understand these connections.
Costing a total of £63m, the facility will be distributed across three sites in northern Scandinavia - in Skibotn, Norway, near Kiruna in Sweden, and near Kaaresuvanto in Finland. The project will start in September 2017 with site preparations beginning in summer 2018. The radar is expected to be operational in 2021.
A key capability of the radar will be to measure an entire 3D volume of the upper atmosphere in unprecedented detail. This is necessary to understand how energetic particles and electrical currents from space affect both the upper and the lower atmosphere. Scientists will be able to take measurements across scales from hundreds of metres to hundreds of kilometres, providing exceptional detail and vast quantities of data, and opening the scope of research that can be carried out.
The northern hemisphere already hosts several EISCAT radars, situated in the so-called auroral oval - where you can see the northern lights or aurora borealis. They take measurements in a region of the Earth's upper atmosphere called the ionosphere - from about 70 to 1000 km altitude. They sample the electron concentration and temperature, and the ion temperature and velocity at a range of altitudes along the radar beam direction. But the current EISCAT radars provide a single pencil beam, so researchers can only look at one small portion of the sky at a given time.
Dr Andrew Kavanagh, UK EISCAT Science Support, based at the British Antarctic Survey, said:
"The new EISCAT_3D radar will measure the ionosphere in lots of different directions simultaneously. It will be like having hundreds of dishes all operating together, looking in different directions. This means we can easily see changes in the ionosphere and don't miss important data: when our measurements change we will be able to say whether something had just appeared or faded or if something was moving through the beams. This is really important as it gives us information about how space weather effects evolve."
The site in Skibotn, Norway will have a transmitter and receiver array, while the two other sites will have receiver arrays. These will generate beams that will 'look into' the transmitted beam and give researchers many intersection heights.
NERC's chief executive, Professor Duncan Wingham, said:
"EISCAT_3D will give us a 3D picture of interactions between space weather and our upper atmosphere with a detail we've not seen before, giving us answers to questions researchers have about the impacts of space weather on the upper atmosphere. We need this information to reduce the risks posed by space weather on our communications systems, satellites and power grids, which we all rely on."
EISCAT Director, Dr Craig Heinselman, said:
"We are very excited to be starting construction of the new EISCAT_3D radar system. Building on over three and a half decades of scientific observations with the legacy EISCAT radars, this new multi-site phased-array radar will allow our international user community to investigate important questions about the physics of the near-Earth space environment. The radar will make measurements at least ten times faster and with ten times finer resolution than current systems. It will also provide fundamentally different measurements which are unique in the scientific world by utilising, initially, fully flexible receive arrays at two separated locations in the Nordic region in concert with the core transmit/receive array. These systems will let us probe phenomena such as the aurora borealis in three dimensions and, in concert with a variety of other measurements, will allow us to uncover the fundamental effects of phenomena such as space weather. EISCAT_3D uses modern analog and digital technologies that enable flexibility now and a path forward for implementing new ideas that emerge from future discoveries. It truly represents a platform for the next generation of space scientists to build upon."
Notes for Editors
Photos available from the NERC Press office, Sylvie Kruiniger tel. 0044 1793 442593
Dr Andrew Kavanagh, UK EISCAT Science Support, based at British Antarctic Survey, is available for interviews w/c 21st August 2017. Contact Athena Dinar, Senior PR & Communications Manager, British Antarctic Survey, firstname.lastname@example.org, Tel: +44 1223 221441, Mobile: +44 7909 008516
EISCAT_3D - https:/
EISCAT, the European Incoherent Scatter Association, is a scientific organization that facilitates research on the atmosphere and space weather using high power ionospheric radars in the Arctic. The UK is one of the six members of the association, represented by the Natural Environment Research Council (NERC). This gives UK scientists access to the facilities operated by EISCAT and the archive of data stretching back to the mid-1980s. The facilities include three radars: two near the Norwegian city of Tromsø and a third on the island of Spitzbergen in the Svalbard archipelago. The radars primarily measure properties of the Earth's ionosphere (density & temperature) and can observe as low as the stratosphere (~20 km altitude) and as high as the top of the ionosphere (~2000 km altitude). As the UK is an EISCAT associate country, UK scientists gain access to the data taken by the radars (stretching back to the mid-1980s) and can apply for observing time to run their own experiments. UK EISCAT science support provides expert help in developing and running experiments and in the interpretation of the measurements that are collected. They manage UK access to the EISCAT facilities via the time allocation process and provide expert advice on use of past radar data.
The EISCAT Scientific Association - comprising research councils and national institutes from Finland, Norway, Sweden, the United Kingdom, Japan and China, with additional members from several other countries (http://www.
EISCAT and the UK The UK has been an associate member of EISCAT since it was founded in December 1975. The current UK contribution to EISCAT is funded by NERC via the British Antarctic Survey (BAS) and the National Centre for Atmospheric Science (NCAS). The UK EISCAT science support group is a partnership between BAS and the STFC Rutherford Appleton Laboratory, funded through NCAS.
NERC is the UK's main agency for funding and managing research, training and knowledge exchange in the environmental sciences. Our work covers the full range of atmospheric, Earth, biological, terrestrial and aquatic science, from the deep oceans to the upper atmosphere and from the poles to the equator. We coordinate some of the world's most exciting research projects, tackling major issues such as climate change, environmental influences on human health, the genetic make-up of life on Earth, and much more. NERC is a non-departmental public body. We receive around £330 million of annual funding from the Department for Business, Energy & Industrial Strategy (BEIS). http://www.
British Antarctic Survey (BAS), an institute of the Natural Environment Research Council (NERC), delivers and enables world-leading interdisciplinary research in the Polar Regions. Its skilled science and support staff based in Cambridge, Antarctica and the Arctic, work together to deliver research that uses the Polar Regions to advance our understanding of Earth as a sustainable planet. Through its extensive logistic capability and know-how BAS facilitates access for the British and international science community to the UK polar research operation. Numerous national and international collaborations, combined with an excellent infrastructure help sustain a world leading position for the UK in Antarctic affairs. For more information visit http://www.
The National Centre for Atmospheric Science (NCAS) is a world leader in atmospheric science, a multi-million pound research centre, funded by the Natural Environment Research Council (NERC). NCAS carries out research in climate science, atmospheric composition and air quality, physics of the atmosphere (including hazardous and extreme weather) and provides the UK community with state-of-the-art technologies for observing and modelling the atmosphere, including a world-leading research aircraft. By its very nature, atmospheric science research is multi-disciplinary, and NCAS works to bring together scientists from a range of core disciplines such as physics, chemistry and mathematics and using state-of-the-art technologies for observing and modelling the atmosphere. NCAS provides scientific facilities for researchers right across the UK to enable excellent atmospheric science on a national scale. These include a world-leading research aircraft, a ground-based instrumentation pool, access to computer models and facilities for storing and accessing data. In a nutshell, we provide the UK academic community and the Natural Environment Research Council with national capability in atmospheric science.
The UK's Science and Technology Facilities Council supports EISCAT and access for UK researchers to the facility through its RAL Space EISCAT Group. Its main objective is studying solar terrestrial physics and in particular the ionosphere, the ionised region of the Earth's atmosphere. https:/