Abstract
Abstract. In anthropogenically influenced atmospheres, sulphur dioxide (SO2) is the main precursor of gaseous sulphuric acid (H2SO4), which in turn is a main precursor for atmospheric particle nucleation. As a result of socio-economic changes, East Germany has seen a dramatic decrease in anthropogenic SO2 emissions between 1989 and present, as documented by routine air quality measurements in many locations. We have attempted to evaluate the influence of changing SO2 concentrations on the frequency and intensity of new particle formation (NPF) using two different data sets (1996–1997; 2003–2006) of experimental particle number size distributions (diameter range 3–750 nm) from the atmospheric research station Melpitz near Leipzig, Germany. Between the two periods SO2 concentrations decreased by 65% on average, while the frequency of NPF events dropped by 45%. Meanwhile, the average formation rate of 3 nm particles decreased by 68% on average. The trends were statistically significant and therefore suggest a connection between the availability of anthropogenic SO2 and freshly formed new particles. In contrast to the decrease in new particle formation, we found an increase in the mean growth rate of freshly nucleated particles (+22%), suggesting that particle nucleation and subsequent growth into larger sizes are delineated with respect to their precursor species. Using three basic parameters, the condensation sink for H2SO4, the SO2 concentration, and the global radiation intensity, we were able to define the characteristic range of atmospheric conditions under which particle formation events take place at the Melpitz site. While the decrease in the concentrations and formation rates of the new particles was rather evident, no similar decrease was found with respect to the generation of cloud condensation nuclei (CCN; particle diameter >100 nm) as a result of atmospheric nucleation events. On the contrary, the production of CCN following nucleation events appears to have increased by tens of percents. Our aerosol dynamics model simulations suggest that such an increase can be caused by the increased particle growth rate.
Highlights
Aerosol particles play a key role in balancing the earth’s radiation budget due to their light-scattering and cloud-forming properties (Haywood and Boucher, 2000) as well as through heterogeneous chemical reactions and the budget of photooxidants (Ravishankara, 1997)
In contrast to the decrease in new particle formation, we found an increase in the mean growth rate of freshly nucleated particles (+22%), suggesting that particle nucleation and subsequent growth into larger sizes are delineated with respect to their precursor species
In East Germany the main pollution sources were associated with carbochemical industry as well as unregulated power plants
Summary
Aerosol particles play a key role in balancing the earth’s radiation budget due to their light-scattering and cloud-forming properties (Haywood and Boucher, 2000) as well as through heterogeneous chemical reactions and the budget of photooxidants (Ravishankara, 1997). A. Hamed et al.: Changes in the production rate of secondary aerosol particles in Central Europe process controlling the number concentration of atmospheric particles is the formation of new ultrafine particles typically 1–2 nm in size, through gas-to particle conversion The new particles can grow through condensation and coagulation to sizes of 50–100 nm where they become active light scatterers and cloud condensation nuclei (CCN). From numerous observations worldwide it is evident that atmospheric aerosol formation followed by condensational growth may occur in almost any part of the troposphere (Kulmala et al, 2004b)
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