Exposure to atmospheric particulate matter (PM) exacerbates respiratory and cardiovascular conditions and is a leading source of premature mortality globally. Organic aerosol contributes a significant fraction of PM in the United States. Here, using surface observations between 1990 and 2012, we show that organic carbon has declined dramatically across the entire United States by 25-50%; accounting for more than 30% of the US-wide decline in PM. The decline is in contrast with the increasing organic aerosol due to wildfires and no clear trend in biogenic emissions. By developing a carbonaceous emissions database for the United States, we show that at least two-thirds of the decline in organic aerosol can be explained by changes in anthropogenic emissions, primarily from vehicle emissions and residential fuel burning. We estimate that the decrease in anthropogenic organic aerosol is responsible for averting 180,000 (117,000-389,000) premature deaths between 1990 and 2012. The unexpected decrease in organic aerosol, likely a consequence of the implementation of Clean Air Act Amendments, results in 84,000 (30,000-164,000) more lives saved than anticipated by the EPA between 2000 and 2010.
Abstract. The elemental composition of organic material in
environmental samples – including atmospheric organic aerosol, dissolved
organic matter, and other complex mixtures – provides insights into their
sources and environmental processing. However, standard analytical
techniques for measuring elemental ratios typically require large sample
sizes (milligrams of material or more). Here we characterize a method for
measuring elemental ratios in environmental samples, requiring only
micrograms of material, using a small-volume nebulizer (SVN). The technique
uses ultrasonic nebulization of samples to generate aerosol particles
(100–300 nm diameter), which are then analyzed using an aerosol mass
spectrometer (AMS). We demonstrate that the technique generates aerosol from
complex organic mixtures with minimal changes to the elemental composition
of the organic material and that quantification is possible using internal
standards (e.g., NH415NO3). Sample volumes of 2–4 µL
with total solution concentrations of at least 0.2 g L−1 form sufficient
particle mass for elemental ratio measurement by the AMS, despite only a
small fraction (∼ 0.1 %) of the sample forming fine
particles after nebulization (with the remainder ending up as larger
droplets). The method was applied to aerosol filter extracts from the field
and laboratory, as well as to the polysaccharide fraction of dissolved
organic matter (DOM) from the North Pacific Ocean. In the case of aerosol
particles, the mass spectra and elemental ratios from the SVN–AMS agree with
those from online AMS sampling. Similarly, for DOM, the elemental ratios
determined from the SVN–AMS agree with those determined using combustion
analysis. The SVN–AMS provides a platform for the rapid quantitative
analysis of the elemental composition of complex organic mixtures and
non-refractory inorganic salts from microgram samples with applications that
include analysis of aerosol extracts and terrestrial, aquatic, and
atmospheric dissolved organic matter.
Abstract. The elemental composition of organic material in environmental samples – including atmospheric organic aerosol, dissolved organic matter, and other complex mixtures – provides insights into their sources and environmental processing. However, standard analytical techniques for measuring elemental ratios typically require large sample sizes (milligrams of material or more). Here we characterize a method for measuring elemental ratios in environmental samples, requiring only micrograms of material, using a Small Volume Nebulizer (SVN). The technique uses ultrasonic nebulization of samples to generate aerosol particles (100–300 nm diameter), which are then analyzed using an aerosol mass spectrometer (AMS). We demonstrate that the technique generates aerosol from complex organic mixtures with minimal changes to the elemental composition of the organic and that quantification is possible using internal standards (e.g., NH415NO3). Sample volumes of 2–4 uL with total solution concentrations of at least 0.2–g/L form sufficient particle mass for elemental ratio measurement by the AMS, despite only a small fraction (~ 0.1 %) of the sample forming fine particles while the remainder end up as larger droplets. The method was applied to aerosol filter extracts from the field and laboratory, as well as to dissolved organic matter (DOM) from the North Pacific Ocean. In the case of aerosol particles, the mass spectra and elemental ratios from the SVN-AMS agree with those from online AMS sampling; similarly, for DOM, the elemental ratios determined from the SVN-AMS agree with those determined using combustion analysis. The SVN-AMS provides a platform for the rapid quantitative analysis of the elemental composition of complex organic mixtures and non-refractory inorganic salts from microgram samples with applications that include analysis of aerosol extracts, and terrestrial and atmospheric dissolved organic matter.
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