A43C-0290
Aerosol Size, CCN, and Black Carbon Properties at a Coastal Site in the Eastern U.S.
Thursday, 17 December 2015
Poster Hall (Moscone South)
Taylor Michael Royalty1, Markus D Petters2, Andrew P Grieshop3, Nicholas Meskhidze1, Robert E Reed1, Brittany Phillips1 and Kyle William Dawson1, (1)North Carolina State University Raleigh, Raleigh, NC, United States, (2)North Carolina State Univ., Raleigh, NC, United States, (3)North Carolina State University at Raleigh, Raleigh, NC, United States
Abstract:
Atmospheric aerosols play an important role in regulating the global radiative budget through direct and indirect effects. To date, the role of sea spray aerosols in modulating climate remains poorly understood. Here we present results from measurements performed at the United States Army Corps of Engineers’ Field Research Facility in Duck, North Carolina, USA. Aerosol mobility size distributions (10-600 nm), refractory black carbon (rBC) and scattering particle size distributions (200-620 nm), and size resolved cloud condensation nuclei distributions (.07% - .6% supersaturation) were collected at the end of a 560m pier. Aerosol characteristics associated with northerly, high wind speed (15+ m s-1) flow originating from an oceanic trajectory are contrasted with aerosol properties observed during a weak to moderate westerly flow originating from a continental trajectory. Both marine and continental air masses had aerosol with bi-modal number size distributions with modes centered at 30nm and 140nm. In the marine air-mass, the CCN concentration at supersaturation of 0.4%, total aerosol number, surface, and volume concentration were low. rBC number concentration (D > 200 nm) associated with the marine air-mass was an order of magnitude less than continental number concentration and indicative of relatively unpolluted air. These measurements are consistent with measurements from other coastal sites under marine influence. The relative proportion of Aitken mode size particles increased from 1:2 to 2:1 while aerosol surface area was < 25 µm2 cm-3, suggesting that conditions upwind were potentially conducive to new particle formation. Overall, these results will contribute a better understanding to composition and size variation of marine aerosols.