"The Michelson Interferometer for Passive Atmospheric Sounding is unique in its possibilities to detect polar stratospheric clouds, since it is the first instrument with the ability to observe these clouds continuously over the polar regions, especially during the polar night," said Michael H�pfner of Germany's Forschungszentrum Karlsruhe GmbH.

Using data collected by MIPAS, a German-designed instrument that observes the atmosphere in middle infrared range, H�pfner and other scientists discovered a belt of nitric acid trihydrate clouds developing in the polar night over Antarctica in 2003, about one month after the first PSCs were detected, which were composed of water crystals.

PSCs have two classifications: Type I clouds contain hydrated droplets of nitric acid and sulphuric acid, while Type II clouds consist of relatively pure water ice crystals.

The presence of NAT was detected because of MIPAS' ability to map the atmospheric concentrations of more than 20 trace gases, including ozone as well as the pollutants that attack it.

"This has been the first evidence for the existence of NAT PSCs on a large scale," H�pfner said. NAT particles, which contain three molecules of water and one molecule of nitric acid, enhance the potential for ozone destruction in polar regions.

The thinning of the ozone is caused by the presence of man-made pollutants in the atmosphere such as chlorine, originating from chlorofluorocarbons and other synthetic pollutants. During the southern hemisphere winter, temperatures drop to very low levels, causing the chemicals in the stratosphere - enveloped in complete darkness during the winter - to freeze and form PSCs that contain chlorine.

Now banned under the Montreal Protocol, CFCs once were used widely in aerosol cans and refrigerators, and they have not vanished from the atmosphere. CFCs themselves are inert, but ultraviolet radiation high in the atmosphere breaks them down into their constituent parts, which can be highly reactive with ozone.

As the polar spring arrives, sunlight returns and creates chemical reactions in PSCs responsible for converting benign forms of chlorine into highly ozone-reactive radicals that spur ozone depletion. A single molecule of chlorine has the potential to break down thousands of molecules of ozone.

NAT PSCs enhance the potential for chlorine activation and can also sediment and irreversibly remove nitrogen from the lower stratosphere, causing a process known as denitrification, which slows the return of chlorine to its inactive form and allows for ozone destruction to continue.

H�pfner and colleagues were able to explain the sudden NAT formation of PSCs in 2003 by temperature disturbances in waves over the Antarctic Peninsula and the Ellsworth Mountains, suggesting a more significant role for mountain waves in the formation of Antarctic's PSCs than previously thought.

He said the presence of PSCs could intensify in the future, due to a globally changing climate, in which Earth's surface grows warmer due to trapped greenhouse gases but the stratosphere gets colder, providing an environment in which the clouds can form. An increase in PSCs could counteract the recovery of the ozone layer.

Scientific efforts to date have focused on determining PSC composition and their formation mechanisms, but the process causing the ozone depletion remains poorly understood. In order to gain a better understanding of ozone depletion, scientists must continue obtaining data - such as data collected by MIPAS - which allows them to measure the key dynamics of the process.

Related Links
ESA Envisat

Memory Foam Mattress Review

SPACE MEDIA NETWORK PROMOTIONS Solar Energy Solutions Tempur-Pedic Mattress Comparison ... Newsletters :: SpaceDaily :: SpaceWar :: TerraDaily :: Energy Daily XML Feeds :: Space News :: Earth News :: War News :: Solar Energy News