Laboratory measurements of trace gas emissions from biomass burning of fuel types from the southeastern and southwestern United States

Burling, I. R.; Yokelson, Robert J.; Griffith, David; Johnson, Timothy J.; Veres, P. R.; Roberts, J. M.; Warneke, C.; Urbanski, S. P.; Reardon, J.; Weise, David R.; Hao, Wei Min; Gouw, J. A. de

doi:10.5194/acp-10-11115-2010

Cited by 242 publications

(318 citation statements)

References 65 publications

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“…The slope of the regression lines of these individual studies was more gentle than the slope we found for the whole dataset. Lab experiments McMeeking et al, 2009;Burling et al, 2010) also show overall higher correlations between MCE and EF CH 4 than our results for all data for the different vegetation biomes combined.…”

Section: Available Ef Datacontrasting

confidence: 44%

Spatial and temporal variability in the ratio of trace gases emitted from biomass burning

Leeuwen¹,

Werf²

2011

Atmos. Chem. Phys.

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Abstract. Fires are a major source of trace gases and aerosols to the atmosphere. The amount of biomass burned is becoming better known, most importantly due to improved burned area datasets and a better representation of fuel consumption. The spatial and temporal variability in the partitioning of biomass burned into emitted trace gases and aerosols, however, has received relatively little attention. To convert estimates of biomass burned to trace gas and aerosol emissions, most studies have used emission ratios (or emission factors (EFs)) based on the arithmetic mean of field measurement outcomes, stratified by biome. However, EFs vary substantially in time and space, even within a single biome. In addition, it is unknown whether the available field measurement locations provide a representative sample for the various biomes. Here we used the available body of EF literature in combination with satellite-derived information on vegetation characteristics and climatic conditions to better understand the spatio-temporal variability in EFs. While focusing on CO, CH 4 , and CO 2 , our findings are also applicable to other trace gases and aerosols. We explored relations between EFs and different measurements of environmental variables that may correlate with part of the variability in EFs (tree cover density, vegetation greenness, temperature, precipitation, and the length of the dry season). Although reasonable correlations were found for specific case studies, correlations based on the full suite of available measurements were lower and explained about 33%, 38%, 19%, and 34% of the variability for respectively CO, CH 4 , CO 2 , and the Modified Combustion Efficiency (MCE). This may be partly due to uncertainties in the environmental variables, differences in measurement techniques for EFs, assumptions on the ratio between flaming and smoldering combustion, and incomplete information on the location and timing of EF Correspondence to: T. T. van Leeuwen (thijs.van.leeuwen@falw.vu.nl) measurements. We derived new mean EFs, using the relative importance of each measurement location with regard to fire emissions. These weighted averages were relatively similar to the arithmetic mean. When using relations between the environmental variables and EFs to extrapolate to regional and global scales, we found substantial differences, with for savannas 13% and 22% higher CO and CH 4 EFs than the arithmetic mean of the field studies, possibly linked to an underrepresentation of woodland fires in EF measurement locations. We argue that from a global modeling perspective, future measurement campaigns could be more beneficial if measurements are made over the full fire season, and if relations between ambient conditions and EFs receive more attention.

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Section: Available Ef Datacontrasting

confidence: 44%

Spatial and temporal variability in the ratio of trace gases emitted from biomass burning

Leeuwen¹,

Werf²

2011

Atmos. Chem. Phys.

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“…Emission factors for biomass burning are primarily based on airborne and ground field measurements and measurements from small fires conducted in laboratories. Laboratory studies have shown that emissions of trace gases and particles from biomass burning can vary widely based on the type of fuel burned as well as the phase of combustion (i.e., whether the combustion is in the early "flaming" stages or the later "smoldering" stages) [4]. However, the size, fuel moisture, and combustion characteristics of laboratory fires may not be representative of large-scale wildfires.…”

Section: Introductionmentioning

confidence: 99%

Emission Ratios for Ammonia and Formic Acid and Observations of Peroxy Acetyl Nitrate (PAN) and Ethylene in Biomass Burning Smoke as Seen by the Tropospheric Emission Spectrometer (TES)

et al. 2011

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Abstract:We use the Tropospheric Emission Spectrometer (TES) aboard the NASA Aura satellite to determine the concentrations of the trace gases ammonia (NH 3 ) and formic acid (HCOOH) within boreal biomass burning plumes, and present the first detection of peroxy acetyl nitrate (PAN) and ethylene (C 2 H 4 ) by TES. We focus on two fresh Canadian plumes observed by TES in the summer of 2008 as part of the Arctic Research of the Composition of the Troposphere from Aircraft and Satellites (ARCTAS-B) campaign. We use TES retrievals of NH 3 and HCOOH within the smoke plumes to calculate their emission ratios (1.0% ± 0.5% and 0.31% ± 0.21%, respectively) relative to CO for these Canadian fires. The TES derived emission ratios for these gases agree well with previous aircraft and satellite estimates, and can complement ground-based studies that have greater surface sensitivity. We find that TES observes PAN mixing ratios of ~2 ppb within these mid-tropospheric boreal biomass burning plumes when the average cloud optical depth is low (<0.1) and that TES can detect C 2 H 4 mixing ratios of ~2 ppb in fresh biomass burning smoke plumes. OPEN ACCESSAtmosphere 2011, 2 634

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“…It has been recognized for many years that biomass burning can be a source of elevated NH 3 concentrations (Hegg et al, 1988), and both laboratory (Burling et al, 2010) and field (Akagi et al, 2013(Akagi et al, , 2014 measurements have documented wildfires and prescribed burning as important NH 3 sources in the Southeast. Although Xing et al (2013) estimates that wildfires typically account for only 1-3% of annual NH 3 emissions in the U.S. and 3-10% of annual emissions in SEARCH states, the incidence of wildfires are expected to increase in the Southeast as a result of continuing global change (Liu et al, 2014).…”

Section: Conclusion and Potential Implicationsmentioning

confidence: 99%

Recent trends in gas-phase ammonia and PM_2.5 ammonium in the Southeast United States

Saylor

Myles

Sibble

et al. 2014

Journal of the Air & Waste Management Association

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Ammonia measurements from the Southeastern Aerosol Research and Characterization (SEARCH) study network were analyzed for trends over 9 yr (2004)(2005)(2006)(2007)(2008)(2009)(2010)(2011)(2012) of observations. Total ammonia concentrations, defined as the sum of gas-phase ammonia and fine particle ammonium, were found to be decreasing by 1-4% yr −1 and were qualitatively consistent with ammonia emission estimates for the SEARCH states of Alabama, Georgia, Mississippi, and Florida. On the other hand, gas-phase ammonia mixing ratios were found to be slightly rising or steady over the region, leading to the observation that the gas-phase fraction of total ammonia has steadily increased over 2004-2012 as a result of declining emissions of the strong acid precursor species sulfur dioxide (SO 2 ) and nitrogen oxides (NO x ) and consequent reduced partitioning of ammonia to the fine particle phase. Because gas-phase ammonia is removed from the atmosphere more rapidly than fine particle ammonium, an increase in the gas-phase fraction of total ammonia may result in shifted deposition patterns as more ammonia is deposited closer to sources rather than transported downwind in fine particles. Additional long-term measurements and modeling studies are needed to determine if similar transitions of total ammonia to the gas phase are occurring outside of the Southeast and to assess if these changes are impacting plants and ecosystems near major ammonia sources. Unusually high ammonia concentrations observed in 2007 in the SEARCH measurements are hypothesized to be linked to emissions from wildfires that were much more prevalent across the Southeast during that year due to elevated temperatures and widespread drought. Although wildfires are currently estimated to be a relatively small fraction (3-10%) of total ammonia emissions in the Southeast, the projected increased incidence of wildfires in this region as a result of global climate change may lead to this source's increased importance over the rest of the 21st century.Implications: Ammonia concentrations from the Southeastern Aerosol Research and Characterization study (SEARCH) network are analyzed over the 9-yr period 2004-2012. Total ammonia (gaseous ammonia + PM 2.5 ammonium) concentrations declined at a rate of 1-4% yr −1 , consistent with U.S. Environmental Protection Agency (EPA) emission estimates for the Southeast United States, but the fraction of ammonia in the gas phase has risen steadily (+1-3% yr −1 ) over the time period. Declining emissions of SO 2 and NO x resulting from imposed air quality regulations have resulted in decreased atmospheric strong acids and less ammonia partitioning to the particle phase, which may impact the amount and overall pattern of ammonia deposition.

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Laboratory measurements of trace gas emissions from biomass burning of fuel types from the southeastern and southwestern United States

Cited by 242 publications

References 65 publications

Spatial and temporal variability in the ratio of trace gases emitted from biomass burning

Spatial and temporal variability in the ratio of trace gases emitted from biomass burning

Emission Ratios for Ammonia and Formic Acid and Observations of Peroxy Acetyl Nitrate (PAN) and Ethylene in Biomass Burning Smoke as Seen by the Tropospheric Emission Spectrometer (TES)

Recent trends in gas-phase ammonia and PM_2.5 ammonium in the Southeast United States

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Laboratory measurements of trace gas emissions from biomass burning of fuel types from the southeastern and southwestern United States

Cited by 242 publications

References 65 publications

Spatial and temporal variability in the ratio of trace gases emitted from biomass burning

Spatial and temporal variability in the ratio of trace gases emitted from biomass burning

Emission Ratios for Ammonia and Formic Acid and Observations of Peroxy Acetyl Nitrate (PAN) and Ethylene in Biomass Burning Smoke as Seen by the Tropospheric Emission Spectrometer (TES)

Recent trends in gas-phase ammonia and PM2.5 ammonium in the Southeast United States

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Recent trends in gas-phase ammonia and PM_2.5 ammonium in the Southeast United States