A11M-0258
Quantifying Ozone Production throughout the Boundary Layer from High Frequency Tethered Profile Measurements during a High Ozone Episode in the Uinta Basin, Utah
Monday, 14 December 2015
Poster Hall (Moscone South)
Chance Wiley Sterling1, Bryan Johnson2, Russell C Schnell1, Samuel J Oltmans3, Patrick Cullis3, Emrys G Hall4, Allen F Jordan3, Jim Windell4, Audra McClure-Begley5, Detlev Helmig6 and Gabrielle Petron7, (1)NOAA Boulder, Boulder, CO, United States, (2)NOAA Boulder, ESRL/GMD, Boulder, CO, United States, (3)Cooperative Institute for Research in Environmental Sciences, Boulder, CO, United States, (4)Global Monitoring Division, NOAA Earth System Research Laboratory, Boulder, CO, United States, (5)University of Colorado at Boulder, Boulder, CO, United States, (6)University of Colorado at Boulder, Institute of Arctic and Alpine Research, Boulder, CO, United States, (7)CIRES, Boulder, CO, United States
Abstract:
During the Uinta Basin Winter Ozone Study (UBWOS) in Jan – Feb 2013, 735 tethered ozonesonde profiles were obtained at 3 sites including during high wintertime photochemical ozone production events that regularly exceeded 125 ppb. High resolution profiles of ozone and temperature with altitude, measured during daylight hours, showed the development of approximately week long high ozone episodes building from background levels of ~40 ppb to >150 ppb. The topography of the basin combined with a strong temperature inversion trapped oil and gas production effluents in the basin and the snow covered surface amplified the sun’s radiation driving the photochemical ozone production at rates up to 13 ppb/hour in a cold layer capped at 1600-1700 meters above sea level. Beginning in mid-morning, ozone mixing ratios throughout the cold layer increased until late afternoon. Ozone mixing ratios were generally constant with height indicating that ozone production was nearly uniform throughout the depth of the cold pool. Although there was strong diurnal variation, ozone mixing ratios increased during the day more than decreased during the night, resulting in elevated levels the next morning; an indication that nighttime loss processes did not compensate for daytime production. Even though the 3 tethersonde sites were at elevations differing by as much as 140 m, the top of the high ozone layer was nearly uniform in altitude at the 3 locations. Mobile van surface ozone measurements across the basin confirmed this capped structure of the ozone layer; the vehicle drove out of high ozone mixing ratios at an elevation of ~1900 meters above sea level, above which free tropospheric ozone mixing ratios of ~50 ppb were measured. Exhaust plumes from a coal-fired power plant in the eastern portion of the basin were intercepted by the tethersondes. The structure of the profiles clearly showed that effluents in the plumes were not mixed downward and thus did not contribute precursor nitrogen oxides to the observed ozone production in the boundary layer.