UCAR Communications
News Releases

NCAR News Release

Joint Press Release from NCAR, NASA, AGU


2003-25 FOR IMMEDIATE RELEASE: July 14, 2003

Satellites See Lightning Strikes in Ozone's Origins

Contact:

David Hosansky
UCAR Communications
Telephone: (303) 497-8611
E-mail: hosansky@ucar.edu

Rob Gutro
NASA Goddard
301-286-4044
E-mail: rgutro@pop900.gsfc.nasa.gov

Harvey Leifert
American Geophysical Union
202-777-7507
E-mail: hleifert@agu.org

Cheryl Dybas
National Science Foundation
703-292-7734
E-mail: cdybas@nsf.gov

BOULDER—Summertime ozone near the Earth's surface forms in most major U.S. cities when sunlight and heat mix with car exhaust and other pollution, causing health officials to issue "ozone alerts." But in other parts of the world, such as the tropical Atlantic, ozone near the Earth's surface appears to originate naturally in ways that have left scientists puzzled. Now, using four satellites, scientists can tell where low-level ozone pollution comes from and whether it is manmade or natural.

Atmospheric scientist David Edwards and his colleagues from the National Center for Atmospheric Research (NCAR), along with collaborators in Canada and Europe, have studied this problem using satellite data from three NASA spacecraft, one satellite from the European Space Agency (ESA), and a computer model from NCAR. They were surprised to find that much more low-atmosphere ozone over the tropical Atlantic develops as a result of lightning than of agricultural or fossil fuel burning. Their findings appeared in a recent issue of the Journal of Geophysical Research – Atmospheres, a publication of the American Geophysical Union (AGU).

The formation of ozone involves several factors, including lightning and pollution from agriculture and fossil fuel burning. The scientists used multiple satellites to look at each factor in turn. NASA satellites included Terra, Earth Probe/TOMS, and the Tropical Rainfall Measuring Mission (TRMM). ESA's ERS-2 satellite was also used, along with NCAR's MOZART-2 (Model for OZone And Related chemical Tracers) computer model, which simulated the chemical composition of the atmosphere. NCAR's primary sponsor is the National Science Foundation (NSF).

The different satellite instruments detected fires, lightning flashes, and the resulting pollution and ozone in the atmosphere. The computer model helped tie all the pieces together.

The scientists found that in the early part of the year, intense fires set by farmers for land-clearing and traditional cultivation in northwest Africa, just south of the Sahara Desert, resulted in large amounts of pollution, which was tracked by the satellites as it spread over the Atlantic towards South America. This pollution greatly increased ozone at low altitudes near the fires.

However, when Edwards and his colleagues examined areas of elevated ozone levels measured by satellites and aircraft over the Atlantic Ocean south of the equator, they were surprised to find that this ozone was caused mainly by lightning rather than the fires.

In other parts of the world, especially near cities, ozone near Earth's surface is often produced from pollution as a result of industrial fossil-fuel burning and cars. Understanding where the pollution comes from in each case is important for improving our air quality.

Fires create smoke and carbon monoxide; lightning creates nitrogen oxides (NOx). All of these come together with other unstable compounds in a chemical soup, in which sunlight helps trigger the reaction that helps form ozone.

The Measurements of Pollution in the Troposphere (MOPITT) instrument aboard NASA's Terra satellite is a joint NASA/Canadian Space Agency mission that measured carbon monoxide concentrations at various levels of the atmosphere. The TOMS instrument on EP/TOMS measured tropical tropospheric ozone over the mid-Atlantic. The TRMM satellite counted the number of fires in a region using its Visible/Infrared Scanner (VIRS), and also catalogued lightning flash data from its Lightning Imaging Sensor (LIS). The satellite data were then interpreted using the MOZART-2 computer model.

Previously, scientists used TOMS observations to get a general idea of where tropospheric ozone levels were high, but it was often difficult to say where the ozone came from and which pollution source or natural process led to its creation. Only recently has the four-satellite combination enabled scientists to make this distinction.

This research was funded by NASA's Earth Science Enterprise (ESE) in cooperation with NSF. NASA's ESE is dedicated to understanding the Earth as an integrated system and applying Earth System Science to improve prediction of climate, weather and natural hazards using the unique vantage point of space.

On the Web:

NASA News release

MOPITT

European Space Agency's GOME

Terra Satellite

TRMM Satellite

TOMS Satellite

U.S. EPA: Ozone: Good Up High, Bad Nearby

The lightning flash average count rate detected by the TRMM/LIS instrument for January 2001.

The vertical column of carbon monoxide for January 2001, measured by the MOPITT instrument. The red areas indicate the highest levels of CO; blue areas show the lowest levels. The white areas occurred where no data were collected due to persistent cloud cover.

To receive UCAR and NCAR news releases by e-mail, fill out our Web form.



The National Center for Atmospheric Research and UCAR Office of Programs are operated by UCAR under the sponsorship of the National Science Foundation and other agencies. Opinions, findings, conclusions, or recommendations expressed in this publication do not necessarily reflect the views of any of UCAR's sponsors. UCAR is an Equal Opportunity/Affirmative Action employer.

UCAR > Communications > News Releases > 2003 Search

Prepared for the web by Carlye Calvin
Last revised: Tuesday, July 15, 2003 10:41 AM