References

ACP

Atmospheric Chemistry and Physics

ACP

1680-7324

Copernicus GmbH

Göttingen, Germany

10.5194/acp-6-2753-2006

Atmospheric oxidation in the Mexico City Metropolitan Area (MCMA) during April 2003

Shirley

T. R.

¹ Brune

W. H.

¹ Ren

¹ Mao

¹ Lesher

¹ Cardenas

² Volkamer

³ Molina

L. T.

³ Molina

M. J.

³ Lamb

⁴ Velasco

⁴ Jobson

⁵ Alexander

⁵

Pennsylvania State University, University Park, PA, USA

Autonomous Metropolitan University, Mexico City, Mexico

Massachusetts Institute of Technology, Cambridge, MA, USA

Washington State University, Pullman, WA, USA

Pacific Northwest National Laboratory, Richland, WA, USA

07 07 2006

6 9 2753 2765

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The Mexico City Metropolitan Area (MCMA) study in April 2003 had measurements of many atmospheric constituents, including OH and HO2. It provided the first opportunity to examine atmospheric oxidation in a megacity in a developing country that has more pollution than typical U.S. and European cities. At midday, OH typically reached 0.35 pptv (~7×106 cm−3), comparable to amounts observed in U.S. cities, but HO2 reached 40 pptv, more than observed in most U.S. cities. The OH reactivity was also measured, even during the highly polluted morning rush hour. MCMA's OH reactivity was 25 s−1 during most of the day and 120 s−1 at morning rush hour, which was several times greater than has been measured in any U.S. city. Median measured and modeled OH and HO2 agreed to within combined uncertainties, although for OH, the model exceeded the measurement by more than 30% during midday. OH production and loss, which were calculated from measurements, were in balance to within uncertainties, although production exceeded loss during morning rush hour. This imbalance has been observed in other cities. The HO2/OH ratio from measurements and steady-state analyses have essentially the same dependence on NO, except when NO was near 100 ppbv. This agreement is unlike other urban studies, in which HO2/OH ratio decreased much less than expected as NO increased. As a result of the active photochemistry in MCMA 2003, the median calculated ozone production from measured HO2 reached 50 ppb h−1, a much higher rate than observed in U.S. cities.

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