Influence of synoptic patterns on surface ozone variability over the eastern United States from 1980 to 2012

We investigate the effect of synoptic-scale weather patterns on observed maximum daily 8-hour average (MDA8) surface ozone over the eastern United States during 1980-2012 in summer (June-August, JJA). Zonally averaged, the relative standard deviation (SD) of daily MDA8 JJA ozone shows a bimodal stru...

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Bibliographic Details
Published in:Atmospheric chemistry and physics 2015-10, Vol.15 (19), p.10925-10938
Main Authors: Shen, L, Mickley, L J, Tai, A P K
Format: Article
Language:English
Subjects:
Air pollution
Air quality
Atmospheric chemistry
Atmospheric models
Bermuda
Climate change
Climate change influences
Climate variability
Climatology
Correlation coefficient
Correlation coefficients
Daily weather
Emissions
Emissions control
Empirical orthogonal functions
Frequency ranges
Future climates
Global temperature changes
Latitude
Low level
Low-level jets
Meteorology
Northeast
Orthogonal functions
Outdoor air quality
Ozone
Ozone decrease
Studies
Summer
Synoptic meteorology
Trends
Variability
Weather
Weather effects
Weather patterns
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Summary:We investigate the effect of synoptic-scale weather patterns on observed maximum daily 8-hour average (MDA8) surface ozone over the eastern United States during 1980-2012 in summer (June-August, JJA). Zonally averaged, the relative standard deviation (SD) of daily MDA8 JJA ozone shows a bimodal structure, with peaks at 28-32 and 40-45 degree N, and we show that those regions are most influenced by the variability in daily weather. We apply empirical orthogonal functions (EOFs) to understand the causes of this structure. The first three leading EOF patterns explain 53 % of the total variance in detrended surface ozone, displaying (1) a widespread response of ozone in the eastern United States associated with north-south movement of jet wind latitude, (2) a north-south pattern linked to the Bermuda High system when its west boundary is located along the east coast, and (3) an east-west pattern characteristic of a westward extension of the Bermuda High and an enhanced Great Plains low level jet (GPLLJ). The northern peak of ozone relative SD can be explained by polar jet activity, while the southern peak appears related to variability in the Bermuda High and GPLLJ. We define a new metric polar jet frequency as the total number of days the jet traverses the Midwest and northeast each summer. In the Midwest and northeast, we find that the correlation coefficient r between detrended mean JJA MDA8 ozone and the polar jet frequency ranges between -0.76 and -0.93 over 1980-2012 depending on the time period selected, suggesting that polar jet frequency could provide a simple metric to predict ozone variability in future climate regimes. In the southeast, the influence of the Bermuda High on mean JJA MDA8 ozone depends on the location of its west edge. For those summers when the average position of the west edge is located west of ~ 85.4 degree W, a westward shift in the Bermuda High west edge increases ozone in the southeast by ~ 1 ppbv deg-1 in longitude. For all summers, a northward shift in the Bermuda High west edge increases ozone over the entire eastern United States by 1-2 ppbv deg-1 in latitude. None of the synoptic patterns identified in this study show a significant trend from 1980 to 2012, confirming that the observed ozone decrease over the eastern United States during this time period is mainly caused by emission controls. Our work underscores the impact of synoptic patterns on ozone variability and suggests that a combination of changing local and syno
ISSN:1680-7324
1680-7316
1680-7324
DOI:10.5194/acp-15-10925-2015