| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 5753308 | Atmospheric Environment | 2017 | 12 Pages |
â¢First O3 lidar profiles during a nocturnal low-level jet in Mid-Atlantic U.S.â¢Observations confirm residual layer pollutants mixing down during onset of jet.â¢Nocturnal turbulent mixing impacted surface O3 and its precursors.â¢Model simulations indicate regional transport and boundary layer entrainment of O3.â¢Surface monitors confirm jet transport can impact the “next-day” chemical budget.
Remotely sensed profiles of ozone (O3) and wind are presented continuously for the first time during a nocturnal low-level jet (NLLJ) event occurring after a severe O3 episode in the Baltimore-Washington D.C. (BW) urban corridor throughout 11-12 June 2015. High-resolution O3 lidar observations indicate a well-mixed and polluted daytime O3 reservoir, which decayed into a contaminated nocturnal residual layer (RL) with concentrations between 70 and 100Â ppbv near 1Â km above the surface. Observations indicate the onset of the NLLJ was responsible for transporting polluted O3 away from the region, while simultaneously affecting the height and location of the nocturnal residual layer. High-resolution modeling analyses and next-day (12 June) lidar, surface, and balloon-borne observations indicate the trajectory of the NLLJ and polluted residual layer corresponds with “next-day” high O3 at sites throughout the southern New England region (New York, Connecticut, Massachusetts). The novel O3 lidar observations are evidence of both nocturnal advection (via high NLLJ wind fields) and entrainment of the polluted residual layer in the presence of the “next-day” convectively growing boundary layer. In the greater context, the novel observational suite described in this work has shown that the chemical budget in areas downwind of major urban centers can be altered significantly overnight during transport events such as the NLLJ.
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