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Dr Andrew Tupper of the Bureau of Meteorology said: "The updates from ESA have been very useful to Darwin VAAC when received in real time, and we expect that in the post-event analysis we'll be able to show lots more potential value."
Satellites help VAACs by providing information on ash and the trace gases, such as sulphur dioxide, erupting into the atmosphere.
ESA sends sulphur dioxide email alerts in near-real time. A map around the location of the sulphur dioxide peak is put on a dedicated web page, provided in the email.
This Support to Aviation Control Service is based on data from ESA's Envisat, Eumetsat's MetOp and NASA's Aura satellites. The animations to the right show the sulphur dioxide plume and its movement from Indonesia towards Australia during 4–13 November. To know whether aircraft may pass safely under or over ash clouds and to forecast cloud movement, the VAACs need more accurate information on the altitude and vertical size of ash plumes.

ESA started the 'Support to Aviation for Volcanic Ash Avoidance' project as a demonstration that uses satellite data and wind measurements to compute the injection heights of volcanic emissions. The animation on the right models the Merapi sulphur dioxide plume height and its movement. Flight disruptions from Mt Merapi's ash cloud echo the situation faced in Europe in April and May when Iceland's Eyjafjallajoekull volcano spewed huge amounts of ash and grounded numerous flights. In May, ESA and Eumetsat co-hosted a meeting with some of the world's leading scientists to look at improving how Earth observation satellites can support the VAACs. ESA and Eumetsat are now working to implement a set of recommendations (available here) that were outlined at the event.

Operational satellites like Europe's Meteosat Third Generation and the planned Global Monitoring for Environment and Security (GMES) Sentinels will ensure volcanic ash monitoring from space well into the future.