Tl. Anderson et al., In situ measurement of the aerosol extinction-to-backscatter ratio at a polluted continental site, J GEO RES-A, 105(D22), 2000, pp. 26907-26915
The extinction-to-backscatter ratio S is a crucial parameter for quantitati
ve interpretation of lidar data, yet empirical knowledge of S for troposphe
ric aerosols is extremely limited. Here we review that knowledge and extend
it using a recently developed in situ technique that employs a 180 degrees
backscatter nephelometer. This technique allows robust quantification of m
easurement uncertainties and permits correlations with other aerosol and me
teorological properties to be explored. During 4 weeks of nearly continuous
measurements in central Illinois, S was found to vary over a wide range, c
onfirming previous indications that geographical location by itself is not
necessarily a good predictor. The data suggest a modest dependence of S on
relative humidity, but this explains only a small portion of the variation.
Most variation was associated with changes between two dominant air mass t
ypes: rapid transport from the northwest and regional stagnation. The latte
r category displayed much higher aerosol concentrations and a systematicall
y higher and more tightly constrained range of S. Averages and standard dev
iations were 64 +/- 4 sr for the stagnant category and 40 +/- 9 sr for the
rapid transport category. Considering the 95% confidence precision uncertai
nty of the measurements, the difference between these averages is at least
13 sr and could be as large as 35 sr. The wavelength dependence of light sc
attering, as measured by a conventional nephelometer, is shown to have some
discriminatory power with respect to S.