Ozone production during an urban air stagnation episode over Nashville, Tennessee

The highest 03 levels observed during the 1995 Southern Oxidants Study in middle Tennessee occurred during a period of air stagnation from July 11 through July 15. Extensive airborne (two fixed wing and one helicopter) and ground-based measurements of the chemistry and meteorology of this episode near Nashville, Tennessee, are presented. In situ airborne measurements include 03, NOy, NO, NO2, SO2, CO, nitrate, hydrocarbons, and aldehydes. Airborne LIDAR 0 3 measurements are also utilized to map the vertical and horizontal extent of the urban plume. The use of multiple instrumented research aircraft permitted highly detailed mapping of the plume chemistry in the vertical and horizontal dimensions. Interactions between the urban Nashville plume (primarily a NOx and hydrocarbon source) and the Gallatin coal-fired power plant plume (primarily a NO x and SO2 source) are also documented, and comparisons of ozone formation in the isolated and mixed urban and power plant plume are presented. The data suggest that during this episode the background air and the edges of the urban plume are NO x sensitive and the core of the urban plume is hydrocarbon sensitive. Under these worst case meteorological conditions, ambient 03 levels well over the level of the new National Ambient Air Quality Standard (NAAQS) for ozone (80 ppb) were observed over and just downwind of Nashville. For example, on July 12, the boundary layer air upwind of Nashville showed 60 to 70 ppb 0 3, while just downwind of the city the urban plume maximum was over 140 ppb 0 3. With a revised ozone standard set at 80 ppb (8 hour average) and upwind levels already within 10 or 20 ppb of the standard, only a slight increase in ozone from the urban area will cause difficulty in attaining the standard at monitors near the core of the urban plume during this type of episode. The helicopter mapping and LIDAR aircraft data clearly illustrate that high O3 levels can occur during stagnation episodes within a few kilometers of and even within the urban area. The extremely light boundary layer winds (1-3 m s-) contributed to the creation of an ozone dome or blob which stayed very near to the city rather than an elongated plume. The small spatial scale of the zone of high O3 concentrations is mapped in detail demonstrating that the regulatory monitoring network failed to document the maximum O_ concentrations. Modelers using such regulatory data to test photochemical algorithms need to bear in mind that magnitude and frequency of urban ozone may be underestimated by monitoring networks, especially in medium-sized urban areas under slow transport conditions. Finally, this effort shows the value of collaborative field measurements from multiple platforms in developing a more complete picture of the chemistry and transport of photochemical 03.

[1]  E. M. Bailey,et al.  O3 and NO y relationships at a rural site , 1994 .

[2]  James F. Meagher,et al.  Relative production of ozone and nitrates in urban and rural power plant plumes: 1. Composite results based on data from 10 field measurement days , 1998 .

[3]  K. W. Ragland,et al.  Ozone and Visibility Reduction in the Midwest: Evidence for Large-Scale Transport , 1977 .

[4]  W. Chameides,et al.  The role of biogenic hydrocarbons in urban photochemical smog: Atlanta as a case study. , 1988, Science.

[5]  J. Meagher,et al.  Measuring inorganic nitrate species with short time resolution from an aircraft platform by dual-channel ozone , 1998 .

[6]  Michael O. Rodgers,et al.  Correlation of ozone with NOy in photochemically aged air , 1993 .

[7]  A. P. Altshuller Some characteristics of ozone formation in the urban plume of St. Louis, MO , 1988 .

[8]  J. Meagher,et al.  The production of O3 in an urban plume: Airborne sampling of the Atlanta urban plume , 1995 .

[9]  E. M. Bailey,et al.  The total reactive oxidized nitrogen levels and the partitioning between the individual species at six rural sites in eastern North America , 1993 .

[10]  S. M. Beck,et al.  Aircraft measurements of NO x over the eastern Pacific and continental United States and implications for ozone production , 1990 .

[11]  P. Crutzen The influence of nitrogen oxides on the atmospheric ozone content , 1970 .

[12]  Cliff I. Davidson,et al.  Dry Deposition of Atmospheric Contaminants: The Relative Importance of Aerodynamic, Boundary Layer, and Surface Resistances , 1992 .

[13]  P. Shepson,et al.  Determination of the relative ozone and PAN deposition velocities at night , 1992 .

[14]  S. Sillman The use of NO y , H2O2, and HNO3 as indicators for ozone‐NO x ‐hydrocarbon sensitivity in urban locations , 1995 .

[15]  L. Kleinman,et al.  Ozone formation at a rural site in the southeastern United States , 1994 .

[16]  F. Fehsenfeld,et al.  Daytime buildup and nighttime transport of urban ozone in the boundary layer during a stagnation episode , 1998 .

[17]  Michael O. Rodgers,et al.  Ozone precursor relationships in the ambient atmosphere , 1992 .

[18]  G. Wolff,et al.  The Chemical and Meteorological Conditions Associated with High and Low Ozone Concentrations in Southeastern Michigan and Nearby Areas of Ontario , 1986 .

[19]  S. Sillman,et al.  Model correlations for ozone, reactive nitrogen, and peroxides for Nashville in comparison with measurements : Implications for O3-NOx-hydrocarbon chemistry , 1998 .

[20]  L. Kleinman,et al.  An overview of the airborne activities during the Southern Oxidants Study (SOS) 1995 Nashville/Middle Tennessee Ozone Study , 1998 .

[21]  F. Fehsenfeld,et al.  Contribution of organic nitrates to the total reactive nitrogen budget at a rural eastern U.S. site , 1990 .

[22]  D. Fahey,et al.  The Measurement of NOx in the Non-Urban Troposphere , 1988 .