Abstract
Abstract. Paired nano- and long-tube Scanning Mobility Particle Sizer (SMPS) systems were operated for four different intensive field campaigns in New York State. Two of these campaigns were at Queens College in New York City, during the summer of 2001 and the winter of 2004. The other field campaigns were at rural sites in New York State. The data with the computed diffusion loss corrections for the sampling lines and the SMPS instruments were examined and the combined SMPS data sets for each campaign were obtained. The diffusion corrections significantly affect total number concentrations, and in New York City, affect the mode structure of the size distributions. The relationship between merged and integrated SMPS total number concentrations with the diffusion loss corrections and the CPC number concentrations yield statistically significant increases (closer to 1) in the slope and correlation coefficient compared to the uncorrected values. The measurements are compared to PM2.5 mass concentrations and ion balance indications of aerosol acidity. Analysis of particle growth rate in comparison to other observations can classify the events and illustrate that urban and rural new particle formation and growth are the result of different causes. Periods of low observed PM2.5 mass, high number concentration, and low median diameter due to small fresh particles are associated with primary emissions for the urban sites; and with particle nucleation and growth for the rural sites. The observations of high PM2.5 mass, lower number concentrations, and higher median diameter are mainly due to an enhancement of photochemical reactions leading to condensation processes in relatively aged air. There are statistically different values for the condensation sink (CS) between urban and rural areas. While there is good association (r2>0.5) between the condensation sink (CS) in the range of 8.35–283.9 nm and PM2.5 mass in the urban areas, there is no discernable association in the rural areas. The average values computed for the CS lie in the range 8.7×10−3–3.5×10−2 s−1.
Highlights
Atmospheric aerosols are ubiquitous in the Earth’s atmosphere and affect our quality of life through many different processes (Hopke, 2009)
Measurements were conducted at the sites of Whiteface Mountain (WFM, Summer 2002) and Pinnacle State Park (PSP, Summer 2004) in rural areas of New York State and at the urban site of Queens College (QC) in New York City in Summer 2001 and Winter 2004
We calculated the coefficient of determination (r2 value) and slope for plots of counts from Nano and LDMA Scanning Mobility Particle Sizer (SMPS) size bins centered on a range of mobility diameters from less than 30 nm to more than 80 nm
Summary
Atmospheric aerosols are ubiquitous in the Earth’s atmosphere and affect our quality of life through many different processes (Hopke, 2009). As additional information comes to light concerning the role of nano particles in aerosol formation and growth, in manufacturing and nanotechnology, in human health effects, and in climate; the measurements of size distributions inclusive of particles in ultrafine (100 nm) size range, while always important and of interest, have gained increasing attention (Buonanno et al, 2009; Chow et al, 2005; Kulmala et al, 2004a; McMurry, 2000; McMurry et al, 1996; Qian et al, 2007; Watson et al, 2006). Disciplines include areas of physics, chemistry, biology, engineering, and electronics.
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