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Good ozone? Bad ozone? What's the difference? And why is NASA interested in measuring ozone?
Find out, next, on Real World.
Have you ever lived in a city that posted an ozone alert on a really hot summer day?
Just what does that alert mean and what causes the problem? It all goes back to basic chemistry.
You see the oxygen we breathe is actually a molecule made up of two oxygen atoms, so
its molecular formula is O2. Ozone is an unstable and reactive form of oxygen that is made up
of three oxygen atoms, so its molecular formula is O3. Now, that difference of one oxygen
atom might seem insignificant, but it's actually a huge deal.
Bad ozone, or ground-level ozone, is actually an air pollution problem that is created when
pollutants like exhaust, paints, cleaning fluids, or other industrial emissions react
with sunlight, creating more of the unstable ozone molecules.
In the troposphere, which is the lowest level of Earth's atmosphere, and the one we're in
right now, ozone's natural concentration is about 10 parts per billion, or about .00001
percent of the atmosphere. According to the Environmental Protection Agency, ozone levels
greater than 80 parts per billion over a long period of time can cause throat and lung irritation
or aggravation of asthma or emphysema. And that brings us back to those ozone alerts.
When levels get high enough to cause problems, alerts are issued and people are asked to
change their regular habits -- things like: drive less, delay mowing, and stay inside
if you have certain health conditions.
Of course, not all ozone is bad. Ninety percent of the ozone in our atmosphere sits in the
stratosphere, the layer of our atmosphere between about 10 and 50 kilometers above Earth.
Stratospheric ozone protects Earth' surface from excessive ultraviolet radiation.
NASA astronauts on the International Space Station have an amazing view of our fragile
atmosphere and the thin line that makes up the ozone layer.
But why is NASA so interested in ozone? Well, let's hear from Dr. Joe Zawodny, an atmospheric
scientist at NASA's Langley Research Center.
In mid 1980s, we discovered that there was an ozone hole in the Antarctic, and shortly
thereafter we discovered that the global ozone layer was decreasing. We discovered that the
reason behind that was due to chlorine compounds released by humans. Chlorine was seen to peak
and then started to decrease in the late 1990s, and we've seen global decrease in ozone flatten
out. It now has a slight increasing trend.
In order to understand how ozone might be changing, it needs to be measured. The most
common unit for measuring ozone is called the Dobson Unit. One Dobson Unit is the number
of molecules of ozone that would be required to create a layer of pure ozone .01 millimeters
thick. Of course, ozone isn't all packed into a single layer in the Earth's atmosphere - it's
dispersed throughout it.
Since NASA doesn't have a way to actually scoop up all the atmosphere and squeeze the
ozone into layers, just how do we measure something that makes up less than .00006 percent
of our atmosphere? For over 30 years, NASA has used the Stratospheric
Aerosol and Gas Experiment, or SAGE, family of instruments to increase our understanding
of the atmosphere and our knowledge about ozone. And the latest generation, SAGE III,
is catching a ride on the International Space Station, bringing a whole new perspective
to the problem.
So SAGE III measures ozone three different ways. We use a method called solar occultation,
where we look at the sun directly with the instrument, and look through the atmosphere
as the sun sets or rises. We can also do the same thing using the moon. The moon's a million
times dimmer, so it's a little bit more difficult, and the third way is we can just look at scattered
sunlight, just look at the atmosphere and look at the blue sky, if you will. Molecules
like ozone have unique absorption features in them that are easily detectable. So when
you see ozone vary, or if you're measuring surface temperature, and you want to know
why you see the variability in the record that you do, what else is going on? What the
aerosols are doing, what some of the important chemical species that control ozone, what
they were doing, and only by understanding that variability can you get at the underlying
variability that you may not fully understand.
The measurements collected from SAGE III will provide valuable information to the global
scientific community --- helping us answer questions like, "How is our global Earth system
changing? How do human activities influence our climate? And . . . What can we do to protect
our atmosphere?"
And NASA scientists will search for those answers by using the numbers -- data collected
from SAGE III - to tell the story.
See you next time, on Real World.