Aerosol emissions from prescribed fires in the United States: A synthesis of laboratory and aircraft measurements

May, Andrew A.; McMeeking, G. R.; Lee, Taesam; Taylor, Jonathan; Craven, J. S.; Burling, I. R.; Sullivan, A.; Akagi, S. K.; Collett, Jeffrey L.; Flynn, M.; Coe, Hugh; Urbanski, S. P.; Seinfeld, John H.; Yokelson, Robert J.; Kreidenweis, Sonia M.

doi:10.1002/2014jd021848

Cited by 143 publications

(273 citation statements)

References 141 publications

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“…The mass ratio of BC and K + apportioned to this factor was similar to that of a biomass burning plume, particularly the high K + proportion typical of herbaceous burning (Turn et al, 1997;Saarikoski et al, 2007;McMeeking et al, 2009;May et al, 2014). However, both BC and K + loading showed significant uncertainty.…”

Section: Factor 4: Carboxylic Acidsmentioning

confidence: 58%

“…This separation of BC-and K + -rich factors was persistent for all PMF solutions with four or more factors. Furthermore, the mass ratios of SO 2− 4 and NO − 3 to BC were much higher than would be expected for biomass burning with enrichment ratios above 10 (Turn et al, 1997; Hays et al, 2005;Saarikoski et al, 2007;McMeeking et al, 2009;May et al, 2014); the relative loading of SO 2− 4 compared to NH + 4 and NO − 3 was also higher than expected for biomass burning . This factor also showed an acidic signature with a neutralization ratio of 0.12.…”

Section: Factor 3: Black Carbonmentioning

confidence: 82%

“…However, both BC and K + loading showed significant uncertainty. The loadings of formate, acetate, Cl − , Br − , C 2 O 2− 4 , and NH + 4 appeared to be higher than expected for biomass burning emissions; the mass ratio of these analytes to BC were enriched by a factor of 3 to 75 relative to typical mass ratios of biomass burning emissions, based on a review of measured herbaceous and woody emissions (Turn et al, 1997;Andreae and Merlet, 2001;Hays et al, 2005;Saarikoski et al, 2007;McMeeking et al, 2009;May et al, 2014). The observed enrichment ratios of this factor above typical biomass burning plumes could be explained by atmospheric processing, for example, the cloud processing suggested by Legrand and de Angelis (1995).…”

Section: Factor 4: Carboxylic Acidsmentioning

confidence: 93%

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Temporally delineated sources of major chemical species in high Arctic snow

et al. 2018

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Abstract. Long-range transport of aerosol from lower latitudes to the high Arctic may be a significant contributor to climate forcing in the Arctic. To identify the sources of key contaminants entering the Canadian High Arctic an intensive campaign of snow sampling was completed at Alert, Nunavut, from September 2014 to June 2015. Fresh snow samples collected every few days were analyzed for black carbon, major ions, and metals, and this rich data set provided an opportunity for a temporally refined source apportionment of snow composition via positive matrix factorization (PMF) in conjunction with FLEXPART (FLEXible PARTicle dispersion model) potential emission sensitivity analysis. Seven source factors were identified: sea salt, crustal metals, black carbon, carboxylic acids, nitrate, noncrustal metals, and sulfate. The sea salt and crustal factors showed good agreement with expected composition and primarily northern sources. High loadings of V and Se onto Factor 2, crustal metals, was consistent with expected elemental ratios, implying these metals were not primarily anthropogenic in origin. Factor 3, black carbon, was an acidic factor dominated by black carbon but with some sulfate contribution over the winter-haze season. The lack of K + associated with this factor, a Eurasian source, and limited known forest fire events coincident with this factor's peak suggested a predominantly anthropogenic combustion source. Factor 4, carboxylic acids, was dominated by formate and acetate with a moderate correlation to available sunlight and an oceanic and North American source. A robust identification of this factor was not possible; however, atmospheric photochemical reactions, ocean microlayer reaction, and biomass burning were explored as potential contributors. Factor 5, nitrate, was an acidic factor dominated by NO − 3 , with a likely Eurasian source and mid-winter peak. The isolation of NO − 3 on a separate factor may reflect its complex atmospheric processing, though the associated source region suggests possibly anthropogenic precursors. Factor 6, non-crustal metals, showed heightened loadings of Sb, Pb, and As, and correlation with other metals traditionally associated with industrial activities. Similar to Factor 3 and 5, this factor appeared to be largely Eurasian in origin. Factor 7, sulfate, was dominated by SO 2− 4 and MS with a fall peak and high acidity. Coincident volcanic activity and northern source regions may suggest a processed SO 2 source of this factor.

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Section: Factor 4: Carboxylic Acidsmentioning

confidence: 58%

Section: Factor 3: Black Carbonmentioning

confidence: 82%

Section: Factor 4: Carboxylic Acidsmentioning

confidence: 93%

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Temporally delineated sources of major chemical species in high Arctic snow

et al. 2018

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“…Corroborating these results, Liu et al [2014] showed that fire smoke particles are composed of approximately 5-10% (by mass) BC as compared to about 50-70% OC. May et al [2014] analyzed a large number of different smoke plumes in the laboratory and for prescribed fires in the United States, and found a range of BC and particulate organic matter (POM; i.e., the sum of OC and associated chemical elements) emission ratios depending on fuel type, fuel composition, and combustion conditions [see Table 4 in May et al, 2014]. However, POM typically dominates the sub-micron aerosol particle composition in most samples.…”

Section: 1002/2016ef000415mentioning

confidence: 99%

“…The choice of the BC/POM ratios must be considered rather arbitrary given the very wide range of possible BC/POM ratios observed during different type of fires [e.g., May et al, 2014]. An estimate of burnable organic material for Pakistan and India is not available.…”

Section: Experiments Set-upmentioning

confidence: 99%

Climate effects of a hypothetical regional nuclear war: Sensitivity to emission duration and particle composition

et al. 2016

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Here, we use a coupled atmospheric-ocean-aerosol model to investigate the plume development and climate effects of the smoke generated by fires following a regional nuclear war between emerging third-world nuclear powers. We simulate a standard scenario where 5 Tg of black carbon (BC) is emitted over 1 day in the upper troposphere-lower stratosphere. However, it is likely that the emissions from the fires ignited by bomb detonations include a substantial amount of particulate organic matter (POM) and that they last more than 1 day. We therefore test the sensitivity of the aerosol plume and climate system to the BC/POM ratio (1:3, 1:9) and to the emission length (1 day, 1 week, 1 month). We find that in general, an emission length of 1 month substantially reduces the cooling compared to the 1-day case, whereas taking into account POM emissions notably increases the cooling and the reduction of precipitation associated with the nuclear war during the first year following the detonation. Accounting for POM emissions increases the particle size in the short-emission-length scenarios (1 day/1 week), reducing the residence time of the injected particle. While the initial cooling is more intense when including POM emission, the long-lasting effects, while still large, may be less extreme compared to the BC-only case. Our study highlights that the emission altitude reached by the plume is sensitive to both the particle type emitted by the fires and the emission duration. Consequently, the climate effects of a nuclear war are strongly dependent on these parameters.

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Impacts of nonrefractory material on light absorption by aerosols emitted from biomass burning

et al. 2014

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We present laboratory measurements of biomass-burning aerosol light-scattering and light absorption coefficients at 405, 532, and 781 nm and investigate their relationship with aerosol composition and fuel type. Aerosol composition measurements included nonrefractory components measured by a high-resolution aerosol mass spectrometer (AMS), composition of refractory black carbon-containing particles by a soot particle aerosol mass spectrometer (SP-AMS), and refractory black carbon measured by a single-particle soot photometer (SP2). All measurements were performed downstream of a thermal denuder system to probe the effects of nonrefractory material on observed optical properties. The fires studied emitted aerosol with a wide range of optical properties with some producing more strongly light-absorbing particles (single-scattering albedo or SSA at 781 nm = 0.4) with a weak wavelength dependence of absorption (absorption Ångström exponent or AAE = 1-2) and others producing weakly light-absorbing particles (SSA at 781 nm~1) with strong wavelength dependence of absorption (AAE~7). Removal of nonrefractory material from the particles by the thermal denuder system led to substantial (20-80%) decreases in light absorption coefficients, particularly at shorter wavelengths, reflecting the removal of light-absorbing material that had enhanced black carbon absorption in internally mixed untreated samples. Observed enhancements of absorption by all mechanisms were at least factors of 1.2-1.5 at 532 nm and 781 nm as determined from the heated samples. A mass absorption cross-section-based approach indicated larger enhancements, particularly at shorter wavelengths.

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Aerosol emissions from prescribed fires in the United States: A synthesis of laboratory and aircraft measurements

Cited by 143 publications

References 141 publications

Temporally delineated sources of major chemical species in high Arctic snow

Temporally delineated sources of major chemical species in high Arctic snow

Climate effects of a hypothetical regional nuclear war: Sensitivity to emission duration and particle composition

Impacts of nonrefractory material on light absorption by aerosols emitted from biomass burning

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