The rocket will fly through the aurora up to 350 kilometers of height. Illustration: Trond Abrahamsen, Andøya Rocket Range
Do you log your jogging trips with an app on your telephone? You’re not alone in using satellites to determine your correct position. Everything from snow ploughs to alarm systems relies on the GPS system.
But what happens when the GPS is incorrect, or doesn’t work at all? Not too serious for your jog, perhaps, but for other users accurate signals are crucial. That’s why it’s important to be able to forecast problems before they occur.
The aurora is a disruptive element
Solar storms create beautiful northern lights (the aurora borealis) in our atmosphere, but they also have a negative impact on navigation and communication systems. Serious users are in a particularly vulnerable position. Offshore activity, for example, is moving further north, and GPS is increasingly used in aviation.
Acupuncture in space: Professor Moen with one of the instruments onboard the rocket. Photo: Hilde Lynnebakken, University of Oslo
“Both the aurora borealis and electron clouds that arise in the wake of solar storms create problems for radio communications and satellite navigation”, explains project manager and physics professor Jøran Moen at the University of Oslo.
“It’s well known that solar storms cause disturbances, particularly in northern areas and around the equator”, he continues. ”But we still don’t know enough about the mechanisms that create these problems.
This knowledge is the key to improving GPS receivers and forecasting of space weather.
Aurora borealis in the daytime too
We usually think of the northern lights as a night time phenomenon, but they can be seen during the day too. “On Svalbard, in the middle of winter, when it is dark around the clock, we can see the aurora during the day” explains Moen.
The aurora is usually less intense and maybe not as spectacular during the day as it is at night, but it is still an important space weather phenomenon.
“We discovered ten years ago by means of radar studies that some very strong flow shears form at the edges of the daytime aurora”, says Moen. “Now we want to study in detail the effect this has on turbulence in the atmosphere around the aurora”.
This video explains how the aurora is formed:
The aurora disrupts radio waves in all frequency bands The disturbances are greatest for radio communications in the HF, VHF and UHF frequency ranges, but they also cause problems for satellite services such as GPS.
We know that there are waves and turbulence in the altitude range from 200-1000 kilometres that spread and block radio waves, but we still have to find out the ultimate physical processes that are causing this.
Designed to fly through the aurora
The primary task of the ICI rocket is to gather data for the scientists on what goes on in the daytime aurora, particularly in areas with extreme conditions. The rocket is equipped with a number of instruments for studying the electron clouds and electron rays that create the aurora.
French and Japanese scientists are also contributing instruments to the rocket, which will fly for 10 minutes up to a maximum height of 350 kilometres.
A lot has to go right
A successful launch will depend on several factors falling into place. “Both the weather gods and the sun god will have to be on our side”, smiles Moen.
“The rocket can’t be launched if there is too much wind. We also have to have the right kind of aurora, in other words the daytime aurora, within the reach of the the rocket trajectory.”
Some of the airspace above northern Scandinavia will be closed during the rocket operation. The actual launch window is 05:00-12:00 GMT every day from 22 November until 6 December.