2019
DOI: 10.5194/acp-19-8523-2019
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Emission of trace gases and aerosols from biomass burning – an updated assessment

Abstract: Since the publication of the compilation of biomass burning emission factors by Andreae and Merlet (2001), a large number of studies have greatly expanded the amount of available data on emissions from various types of biomass burning. Using essentially the same methodology as Andreae and Merlet (2001), this paper presents an updated compilation of emission factors. The data from over 370 published studies were critically evaluated and integrated into a consistent format. Several new categories of biomass burn… Show more

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Cited by 636 publications
(815 citation statements)
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References 145 publications
(191 reference statements)
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“…Efficient removal from the atmospheric boundary layer via wet and dry deposition reduces their global lifetime to ∼2.3 and 3.2 days, respectively (Paulot et al, 2011); therefore, the abundance of both compounds drops off outside the source regions. Over the biomass burning areas, the ratios are similarly close to 1, although higher fire emission factors for CH 3 COOH than for HCOOH are reported in the literature (Akagi et al, 2011;Andreae, 2019). While we cannot rule out potential retrieval biases, another explanation is a rapid secondary HCOOH formation, as suggested by space-based pyrogenic HCOOH enhancement ratios that are significantly higher than expected (Chaliyakunnel et al, 2016;Pommier et al, 2017), and which would not be present to the same degree for CH 3 COOH.…”
Section: 1029/2019gl086239supporting
confidence: 64%
“…Efficient removal from the atmospheric boundary layer via wet and dry deposition reduces their global lifetime to ∼2.3 and 3.2 days, respectively (Paulot et al, 2011); therefore, the abundance of both compounds drops off outside the source regions. Over the biomass burning areas, the ratios are similarly close to 1, although higher fire emission factors for CH 3 COOH than for HCOOH are reported in the literature (Akagi et al, 2011;Andreae, 2019). While we cannot rule out potential retrieval biases, another explanation is a rapid secondary HCOOH formation, as suggested by space-based pyrogenic HCOOH enhancement ratios that are significantly higher than expected (Chaliyakunnel et al, 2016;Pommier et al, 2017), and which would not be present to the same degree for CH 3 COOH.…”
Section: 1029/2019gl086239supporting
confidence: 64%
“…Following the same approach as in Fig 12, the BC:CO in Fig 13 suggests a more clear fire signal for the ESE and SSE wind directions. Note that the time period used in this plot differs form that in Fig 12 and contains fewer data points, yet some of those points fall on the reference slopes of Andreae (2019). In general terms, even though fire signals are measured at ATTO during nighttime for positive CH 4 gradients as suggested by Fig 13, the nighttime CH 4 enhancements at 79 m are not fully explained by combustion.…”
Section: Rejecting Biomass Burning Influence On Positive Ch 4 Gradientsmentioning
confidence: 94%
“…The timing of the biomass burning season coincides with the dry season in the Amazon region (Gatti et al, 2014;van der Laan-Luijkx et al, 2015;Aragão et al, 2018), thus one could think that CH 4 from combustion is responsible for the positive gradients presented here. During biomass burning, in particular in the case of incomplete combustion, CH 4 is co-emitted 10 together with carbon monoxide (CO), amongst other gases and particles (Akagi et al, 2011;Kirschke et al, 2013;Andreae, 2019). Because CO is emitted in large quantities and due to its low background mixing ratio, this species is considered a good proxy for biomass burning and it can be used as a reference to get an idea of enhancement ratios due to fire emissions.…”
Section: Rejecting Biomass Burning Influence On Positive Ch 4 Gradientsmentioning
confidence: 99%
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“…The EFs used in this study (Table 3) are based on Andreae and Merlet (2001), with updates from field and laboratory studies over various land cover types published during 2001-2018 (Andreae, 2019). All FireMIP model simulations used the same EFs from Table 3.…”
Section: Estimates Of Fire Trace Gas and Aerosol Emissionsmentioning
confidence: 99%