Doubling of annual ammonia emissions from the peat fires in Indonesia during the 2015 El Niño

Whitburn, Simon; Damme, Martin Van; Turquety, Solène; Clerbaux, Cathy; Coheur, Pierre‐François

doi:10.1002/2016gl070620

Cited by 54 publications

(58 citation statements)

References 38 publications

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“…1, panel b) are only found close to the source of emissions due to the relatively short lifetime of NO 2 (of a few hours; Schreier et al, 2014b). With a lifetime of typically 12-36 h in the studied regions (Dentener and Crutzen, 1994;Aneja et al, 2001;Whitburn et al, , 2016a, NH 3 is more likely to be transported over longer distances. This can be seen on the NH 3 -CO correlation map on which positive correlations are also found over seas downwind of the source areas.…”

Section: Selection Of the Areas And Biomes And Calculation Of The Er mentioning

confidence: 90%

“…With a contribution estimated to be about 13 % (Galloway et al, 2004) of the total emissions, biomass burning is believed to be the second most important source of NH 3 after agriculture. From previous studies, it has been shown that biomass burning could significantly affect NH 3 concentrations in the atmosphere, especially in the tropics but also at higher latitudes (e.g., Bouwman et al, 1997;Coheur et al, 2009;Adon et al, 2010;Alvarado et al, 2011;Shephard et al, 2011;Adon et al, 2013;R'Honi et al, 2013;Whitburn et al, , 2016aBenedict et al, 2017;Warner et al, 2017). Excess NH 3 in the environment is of great concern since it is responsible for many environmental is-sues such as eutrophication of terrestrial and aquatic ecosystems, soil acidification, and loss of plant diversity (Aneja et al, 2001;Erisman et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

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IASI-derived NH<sub>3</sub> enhancement ratios relative to CO for the tropical biomass burning regions

et al. 2017

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Abstract. Vegetation fires are a major source of ammonia (NH 3 ) in the atmosphere. Their emissions are mainly estimated using bottom-up approaches that rely on uncertain emission factors. In this study, we derive new biome-specific NH 3 enhancement ratios relative to carbon monoxide (CO), ER NH 3 / CO (directly related to the emission factors), from the measurements of the IASI sounder onboard the Metop-A satellite. This is achieved for large tropical regions and for an 8-year period (2008-2015). We find substantial differences in the ER NH 3 / CO ratios between the biomes studied, with calculated values ranging from 7 × 10 −3 to 23 × 10 −3 . For evergreen broadleaf forest these are typically 50-75 % higher than for woody savanna and savanna biomes. This variability is attributed to differences in fuel types and size and is in line with previous studies. The analysis of the spatial and temporal distribution of the ER NH 3 / CO ratio also reveals a (sometimes large) within-biome variability. On a regional level, woody savanna shows, for example, a mean ER NH 3 / CO ratio for the region of Africa south of the Equator that is 40-75 % lower than in the other five regions studied, probably reflecting regional differences in fuel type and burning conditions. The same variability is also observed on a yearly basis, with a peak in the ER NH 3 / CO ratio observed for the year 2010 for all biomes. These results highlight the need for the development of dynamic emission factors that take into better account local variations in fuel type and fire conditions. We also compare the IASI-derived ER NH 3 / CO ratio with values reported in the literature, usually calculated from ground-based or airborne measurements. We find general good agreement in the referenced ER NH 3 / CO ratio except for cropland, for which the ER NH 3 / CO ratio shows an underestimation of about 2-2.5 times.

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Section: Selection Of the Areas And Biomes And Calculation Of The Er mentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

IASI-derived NH<sub>3</sub> enhancement ratios relative to CO for the tropical biomass burning regions

et al. 2017

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“…We gained the data upon request from the Atmospheric Spectroscopy Group at Université Libre De Bruxelles (http://www.ulb.ac.be/cpm/atmosphere.html). These data can be gridded on 0.1 • latitude × 0.1 • longitude (Dammers et al, 2016), 0.25 • latitude × 0.25 • longitude (Whitburn et al, 2016a) and 0.5 • latitude × 0.5 • longitude (Whitburn et al, 2016b) or even coarser resolutions depending on the usage of the data. For IASI NH 3 , we firstly divided China into a 0.5 • latitude × 0.5 • longitude grid.…”

Section: Satellite Observationsunclassified

Temporal characteristics of atmospheric ammonia and nitrogen dioxide over China based on emission data, satellite observations and atmospheric transport modeling since 1980

Liu

Zhang

et al. 2017

Atmos. Chem. Phys.

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Abstract. China is experiencing intense air pollution caused in large part by anthropogenic emissions of reactive nitrogen (N r ). Atmospheric ammonia (NH 3 ) and nitrogen dioxide (NO 2 ) are the most important precursors for N r compounds (including N 2 O 5 , HNO 3 , HONO and particulate NO − 3 and NH + 4 ) in the atmosphere. Understanding the changes in NH 3 and NO 2 has important implications for the regulation of anthropogenic N r emissions and is a requirement for assessing the consequence of environmental impacts. We conducted the temporal trend analysis of atmospheric NH 3 and NO 2 on a national scale since 1980 based on emission data (during 1980-2010), satellite observation (for NH 3 since 2008 and for NO 2 since 2005) and atmospheric chemistry transport modeling (during 2008-2015).Based on the emission data, during 1980-2010, significant continuous increasing trends in both NH 3 and NO x were observed in REAS (Regional Emission inventory in Asia, for NH 3 0.17 and for NO x 0.16 kg N ha −1 yr −2 ) and EDGAR (Emissions Database for Global Atmospheric Research, for NH 3 0.24 and for NO x 0.17 kg N ha −1 yr −2 ) over China. Based on the satellite data and atmospheric chemistry transport model (CTM) MOZART-4 (Model for Ozone and Related chemical Tracers, version 4), the NO 2 columns over China increased significantly from 2005 to 2011 and then decreased significantly from 2011 to 2015; the satelliteretrieved NH 3 columns from 2008 to 2014 increased at a rate of 2.37 % yr −1 . The decrease in NO 2 columns since 2011 may result from more stringent strategies taken to control NO x emissions during the 12th Five Year Plan, while no control policy has focused on NH 3 emissions. Our findings provided an overall insight into the temporal trends of both NO 2 and NH 3 since 1980 based on emission data, satellite observations and atmospheric transport modeling. These findings can provide a scientific background for policy makers that are attempting to control atmospheric pollution in China. Moreover, the multiple datasets used in this study have implications for estimating long-term N r deposition datasets to assess its impact on soil, forest, water and greenhouse balance.

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“…The emissions from Indonesian peat fires during the 2015 El Niño were estimated using mean EFs calculated in this study for an estimated burned area of 8.5× 10 5 ha (Whitburn et al, 2016), an average burning depth of 34 ± 12 cm (calculated during this study; Stockwell et al, 2016), and a peat bulk density of 0.120 ± 0.005 g cm −3 (Konecny et al, 2016). The uncertainty of the estimated value is propagated using standard deviation of the mean EFs, burn depth, and peat bulk density.…”

Section: Emission Estimates From 2015 Indonesian Peat Firesmentioning

confidence: 99%

Chemical characterization of fine particulate matter emitted by peat fires in Central Kalimantan, Indonesia, during the 2015 El Niño

et al. 2018

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Abstract. Fine particulate matter (PM 2.5 ) was collected in situ from peat smoke during the 2015 El Niño peat fire episode in Central Kalimantan, Indonesia. Twenty-one PM samples were collected from 18 peat fire plumes that were primarily smoldering with modified combustion efficiency (MCE) values of 0.725-0.833. PM emissions were determined and chemically characterized for elemental carbon (EC), organic carbon (OC), water-soluble OC, water-soluble ions, metals, and organic species. Fuel-based PM 2.5 mass emission factors (EFs) ranged from 6.0 to 29.6 g kg −1 with an average of 17.3 ± 6.0 g kg −1 . EC was detected only in 15 plumes and comprised ∼ 1 % of PM mass. Together, OC (72 %), EC (1 %), water-soluble ions (1 %), and metal oxides (0.1 %) comprised 74 ± 11 % of gravimetrically measured PM mass. Assuming that the remaining mass is due to elements that form organic matter (OM; i.e., elements O, H, N) an OM-to-OC conversion factor of 1.26 was estimated by linear regression. Overall, chemical speciation revealed the following characteristics of peat-burning emissions: high OC mass fractions (72 %), primarily water-insoluble OC (84 ± 11 %C), low EC mass fractions (1 %), vanillic to syringic acid ratios of 1.9, and relatively high n-alkane contributions to OC (6.2 %C) with a carbon preference index of 1.2-1.6. Comparison to laboratory studies of peat combustion revealed similarities in the relative composition of PM but greater differences in the absolute EF values. The EFs developed herein, combined with estimates of the mass of peat burned, are used to estimate that 3.2-11 Tg of PM 2.5 was emitted to atmosphere during the 2015 El Niño peatland fire event in Indonesia. Combined with gas-phase measurements of CO 2 , CO, CH 4 , and volatile organic carbon from Stockwell et al. (2016), it is determined that OC and EC accounted for 2.1 and 0.04 % of total carbon emissions, respectively. These in situ EFs can be used to improve the accuracy of the representation of Indonesian peat burning in emission inventories and receptor-based models.

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Doubling of annual ammonia emissions from the peat fires in Indonesia during the 2015 El Niño

Cited by 54 publications

References 38 publications

IASI-derived NH<sub>3</sub> enhancement ratios relative to CO for the tropical biomass burning regions

IASI-derived NH<sub>3</sub> enhancement ratios relative to CO for the tropical biomass burning regions

Temporal characteristics of atmospheric ammonia and nitrogen dioxide over China based on emission data, satellite observations and atmospheric transport modeling since 1980

Chemical characterization of fine particulate matter emitted by peat fires in Central Kalimantan, Indonesia, during the 2015 El Niño

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Doubling of annual ammonia emissions from the peat fires in Indonesia during the 2015 El Niño

Cited by 54 publications

References 38 publications

IASI-derived NH&lt;sub&gt;3&lt;/sub&gt; enhancement ratios relative to CO for the tropical biomass burning regions

IASI-derived NH&lt;sub&gt;3&lt;/sub&gt; enhancement ratios relative to CO for the tropical biomass burning regions

Temporal characteristics of atmospheric ammonia and nitrogen dioxide over China based on emission data, satellite observations and atmospheric transport modeling since 1980

Chemical characterization of fine particulate matter emitted by peat fires in Central Kalimantan, Indonesia, during the 2015 El Niño

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IASI-derived NH<sub>3</sub> enhancement ratios relative to CO for the tropical biomass burning regions

IASI-derived NH<sub>3</sub> enhancement ratios relative to CO for the tropical biomass burning regions