The dynamical evolution and air-quality impacts of the smoke plumes from 2016 Southeastern Wildfires

The 2016 Southeastern United States Wildfires are a series of wildfires along the Southern Appalachians during October-December in 2016, which approximately burned 127,555 acres (about 516 km2) in Georgia, Tennessee, North Carolina and South Carolina (see Incident Information System at https://inciweb.nwcg.gov/). This study will focus on the dynamical evolution and air-quality impacts of the smoke plumes within a short-term, but representative period during this wildfires event. This study combined remote-sensing data and in situ measurements with trajectory model to detect low-altitude smoke plume transport due to the 2016 southeastern wildfire. The smoke plumes were observed by ceilometer to arrive over Huntsville, AL area at low altitude and subsequently mixed down to the surface from Nov 12 to Nov 14. The wildfire had adverse effects on the surface air quality over the southeast region from both satellite and in situ measurement. The daily max 8-hour CO and daily mean PM2.5 data in five states were examined to show the influence. Both rural and urban sites were analyzed to track the wildfire and anthropogenic sources. Backward trajectory model calculation preliminarily confirmed the origin of the smoke plumes over Huntsville area, the transport at low altitudes, and the mechanism for bringing the pollutants to the surface.