Abstract
Abstract. Long-term measurements of atmospheric mass concentrations of black carbon (BC) are needed to investigate changes in its emission, transport, and deposition. However, depending on instrumentation, parameters related to BC such as aerosol absorption coefficient (babs) have been measured instead. Most ground-based measurements of babs in the Arctic have been made by filter-based absorption photometers, including particle soot absorption photometers (PSAPs), continuous light absorption photometers (CLAPs), Aethalometers, and multi-angle absorption photometers (MAAPs). The measured babs can be converted to mass concentrations of BC (MBC) by assuming the value of the mass absorption cross section (MAC; MBC= babs/ MAC). However, the accuracy of conversion of babs to MBC has not been adequately assessed. Here, we introduce a systematic method for deriving MAC values from babs measured by these instruments and independently measured MBC. In this method, MBC was measured with a filter-based absorption photometer with a heated inlet (COSMOS). COSMOS-derived MBC (MBC (COSMOS)) is traceable to a rigorously calibrated single particle soot photometer (SP2), and the absolute accuracy of MBC (COSMOS) has been demonstrated previously to be about 15 % in Asia and the Arctic. The necessary conditions for application of this method are a high correlation of the measured babs with independently measured MBC and long-term stability of the regression slope, which is denoted as MACcor (MAC derived from the correlation). In general, babs–MBC (COSMOS) correlations were high (r2= 0.76–0.95 for hourly data) at Alert in Canada, Ny-Ålesund in Svalbard, Barrow (NOAA Barrow Observatory) in Alaska, Pallastunturi in Finland, and Fukue in Japan and stable for up to 10 years. We successfully estimated MACcor values (10.8–15.1 m2 g−1 at a wavelength of 550 nm for hourly data) for these instruments, and these MACcor values can be used to obtain error-constrained estimates of MBC from babs measured at these sites even in the past, when COSMOS measurements were not made. Because the absolute values of MBC at these Arctic sites estimated by this method are consistent with each other, they are applicable to the study of spatial and temporal variation in MBC in the Arctic and to evaluation of the performance of numerical model calculations.
Highlights
Black carbon (BC) aerosols strongly absorb solar radiation and thereby impact the radiation budget in the Arctic (Bond et al, 2013; AMAP, 2015)
We have shown that in general babs values obtained by particle soot absorption photometers (PSAPs), continuous light absorption photometers (CLAPs), Aethalometer, and multi-angle absorption photometers (MAAPs) were strongly correlated with mass concentrations of BC (MBC) (COSMOS) at all four Arctic sites, the strength of the correlations differed somewhat among the sites
The accuracy of MBC estimated from absorption coefficients measured by these instruments has not been adequately assessed, mainly because of a lack of simultaneous and reliable MBC measurements
Summary
Black carbon (BC) aerosols strongly absorb solar radiation and thereby impact the radiation budget in the Arctic (Bond et al, 2013; AMAP, 2015). BC is one of the short-lived climate forcers (SLCFs), and reductions of BC emissions can decrease the positive Arctic radiative forcing over much shorter timescales than reductions of CO2 emissions can (Sand et al, 2016). Long-term measurements of mass concentrations of BC in the atmosphere (MBC [μg m−3]) at various locations provide fundamental data for the detection of long-term trends in MBC in the Arctic that are associated with changes in BC emissions. Such MBC data are useful for validation and improvement of climate models. Because many long-term surface instruments measure aerosol light absorption coefficient (babs [Mm−1]) rather than MBC, there are large uncertainties in MBC estimated from the measurements of babs; these uncertainties have not been critically evaluated
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