Abstract
Abstract. Tethered balloon-borne aerosol measurements were conducted at Syowa Station, Antarctica during the 46th Japanese Antarctic expedition (2005–2006). The CN concentration reached a maximum in the summer, although the number concentrations of fine particles (Dp>0.3 μm) and coarse particles (Dp>2.0 μm) increased during the winter–spring. The CN concentration was 30–2200 cm−3 near the surface (surface – 500 m) and 7–7250 cm−3 in the lower free troposphere (>1500 m). During the austral summer, higher CN concentration was often observed in the lower free troposphere, where the number concentrations in fine and coarse modes were remarkably lower. The frequent appearance of higher CN concentrations in the free troposphere relative to continuous aerosol measurements at the ground strongly suggests that new particle formation is more likely to occur in the lower free troposphere in Antarctic regions. Seasonal variations of size distribution of fine-coarse particles show that the contribution of the coarse mode was greater in the winter–spring than in summer because of the dominance of sea-salt particles in the winter–spring. The number concentrations of fine and coarse particles were high in air masses from the ocean and mid-latitudes. Particularly, aerosol enhancement was observed not only in the boundary layer, but also in the lower free troposphere during and immediately after Antarctic haze events occurring in May, July and September.
Highlights
Atmospheric aerosol particles are closely related to climate change through direct and indirect effects (e.g., IPCC, 2007)
To compare air mass history and aerosol data, the five-day backward trajectory was computed from heights of 100–2500 m above ground level over Syowa Station using vertical motion mode in the NOAA-HYSPLIT model with “NCEP reanalysis” data (Draxler and Rolph, 2011)
Vertical transport of air mass in the marine boundary layer, can engender higher concentrations of both aerosols and aerosol precursors in the lower free troposphere, so that removal processes of aerosols might be necessary for favourable conditions for new particle formation in the condensation nuclei (CN)-enhanced layer
Summary
Atmospheric aerosol particles are closely related to climate change through direct and indirect effects (e.g., IPCC, 2007). Previous aerosol measurements in the upper atmosphere of Antarctic regions were conducted using (1) airplanes (Iwasaka et al, 1985; Yamazaki et al, 1989; Yamanouchi et al, 1999; Wada et al, 2001; Hara et al, 2006; Osada et al, 2006), (2) balloon-borne particle counters (i.e., aerosol sonde) (Ito et al, 1986; Hayashi, 2001), and (3) tethered balloons (Rankin and Wolff, 2002). Vertical and seasonal distributions of the aerosol number concentration and constituents in the upper atmosphere, are poorly known for Antarctic regions because aerosol measurements in the free troposphere over Antarctica are limited. Tethered balloon-borne aerosol measurements can and safely obtain aerosol samples and the number concentrations, the observable altitude is restricted by the winch-line length and wind speed. The aerosol number concentrations were converted to those under the standard condition (0 ◦C and 1013 hPa)
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