Written by Dr. Tony Phillips
Science at NASA
Washington, D.C. – Ozone stinks. People who breathe it gag as their lungs burn. The EPA classifies ground-level ozone as air pollution.
Yet without it, life on Earth would be impossible.
A fragile layer of ozone 25 km above Earth’s surface is all that stands between us and some of the harshest UV rays from the sun. The ozone molecule O3 blocks radiation which would otherwise burn skin and cause cancer.On Mars, which has no ozone layer to protect it, solar UV rays strafe the surface with deadly effect, leaving the apparently lifeless planet without the simplest of organic molecules in the upper millimeters of exposed Martian soil.
To keep track of our planet’s ozone layer, NASA is about to launch the most sophisticated space-based ozone sensor ever: SAGE III, slated for installation on the International Space Station in 2014.
“The ISS is in the perfect orbit for SAGE III,” says Joe Zawodny, Project Scientist for the instrument at the Langley Research Center. “It will be able to monitor ozone all around the Earth during all seasons of the year.”
SAGE III works by using the Sun and Moon as light sources. When either one rises or sets behind the edge of the Earth, SAGE III analyzes the light that passes through Earth’s atmosphere. Ozone and other molecules absorb specific wavelengths that reveal their density, temperature and location.
“SAGE III is, essentially, analyzing the colors of the sunset to track ozone,” says Zawodny. “It sounds romantic, but this is hard science.”
Researchers began to worry about ozone in the early 1970s when University of California chemists Frank “Sherry” Rowland and Mario Molina testified before Congress that manmade CFCs, a key ingredient of common aerosol sprays, could destroy ozone in the stratosphere. Their fears were soon realized. In 1985, researchers with the British Antarctic Survey announced abnormally low ozone concentrations above Halley Bay near the South Pole. Our planet had an “ozone hole,” and it was rapidly growing.
Because of this agreement, ozone is now on the mend. Ozone holes still open every year above the South Pole, but thanks to the treaty, ozone-destroying chemicals have either leveled off or decreased. At this rate, the ozone layer could recover almost fully by 2050.
To insure that ozone really is recovering–and to alert the world if it is not–NASA has been flying ozone sensors in Earth orbit for decades.
The first of the SAGE sensors rode to space on Earth observing satellites in the late-1970s and early-80s. SAGE II data helped confirm the decline of the ozone layer and measured the effect of the Mt. Pinatubo eruption on the stratosphere. A SAGE III sensor onboard the Russian Meteor-3M satellite extended the ozone record into the 2000s with higher precision than ever.
It is not unusual for researchers to refer to SAGE as “the gold standard” in ozone monitoring. “The SAGE ozone product has a high accuracy, better than 1% in the mid-to-lower stratosphere, and a very high vertical resolution of 1km or better,” says Zawodny.
When SAGE III reaches the space station, it will measure ozone deeper into the atmosphere than ever before, reaching all the way down into the troposphere where planes fly and people live.
“From ISS, SAGE III will get a global picture of tropospheric ozone,” says Zawodny. “I suspect there will be a few surprises in those measurements.”
SAGE III probes Arctic regions, too. Using the Moon as a light source, SAGE III can to detect ozone during the darkness of polar winter where other satellites have trouble seeing.
It’s enough to make a hard-nosed researcher wax eloquent: “Images of the moon and sun rising and setting are dramatic and spectacular,” says Zawodny. “The interplay between the source of light and the environment delights the senses and stirs the imagination. The ability for SAGE III to turn those perceptions into something meaningful is a great pleasure.”
In other words, stay tuned for some beautiful ozone data.