The ionosphere is the final layer of atmosphere before space. This highly dynamic region is constantly exposed to the full intensity of the Sun, harsh ultraviolet radiation breaking down molecules and atoms. Highly charged ions and free electrons therefore fill the ionospheric layers. Critical to terrestrial communications, the ionosphere also plays host to the largest lightshow on Earth, the Aurora. Now NASA-funded research has developed a live “4D Ionosphere” plugin for Google Earth. Now you can fly through the atmosphere’s uppermost reaches without even leaving your desk…



The ionosphere is highly important to us. Radio operators will be acutely aware about how the ionosphere influences radio wave propagation. Ever since Guglielmo Marconi’s experiments with trans-Atlantic radio communications in 1901 between England and the US, the ionosphere has influenced our ability to communicate over large distances, and without the aid of modern satellite technology. The ionosphere creates a charged, reflective barrier that radio waves can be bounced off (bypassing the blocking effect of the curvature of the Earth). However, radio signals are highly influenced by variations in the ionosphere and can be “blacked out” should a major solar storm pump charged particles into the magnetosphere and ionosphere. Even modern Global Positioning Satellite (GPS) signals are influenced by this atmospheric layer, reflecting and attenuating radio waves. As aircraft, ships and other modes of transport now depend on GPS positioning, it is essential that we fully comprehend the physics behind the ionosphere.

In the aim to have a better grasp of the state of the ionosphere, a “live” plugin for Google Earth has just been announced. Funded by NASA’s Living With a Star (LWS) program, it is hoped that this tool can be used by the public and professionals alike to see the current state of the electron content of the ionosphere. Once downloaded and running, the viewer can rotate the globe and see where electron density is high and where it is low. In dense regions, it is very hard for radio waves to propagate, signifying that radio quality will be poor, or blocked all together. In Google Earth, these regions are highlighted in red. The blue regions show “normal” radio propagation regions, expect good quality signal in those locations.

The reason why this new system has been dubbed “4D Ionosphere” is that you can view the ionosphere in three spatial dimensions, and the data is refreshed every ten minutes to give the extra time dimension.

This isn’t the first time Google Earth has been used by organizations for space-based research. On February 24th, I reported that a plugin had been released to track the space debris currently orbiting our planet. Nancy also gave the new Google Sky a test drive in March, a great way to learn about astronomy through this user friendly interface.

I can see lots of applications for this tool already. Firstly I’d be very excited to compare the ionosphere during periods of high solar activity with periods when the Sun experiences solar minimum (like now). This would be especially exciting in Polar Regions in the auroral zone when high quantities of solar wind particles ignite aurorae. Also, there are possible applications for amateur radio (ham) operators who could use this as a means to forecast the strength of the radio signal during campaigns. I am however uncertain how accurate or how detailed these measurements will be, but it at least gives a very interesting look into the current state of this interesting region of the atmosphere.

Source: NASA