Characterizing the 2015 Indonesia Fire Event Using Modified
MODIS Aerosol Retrievals

Shi, Yingxi; Levy, Robert C.; Eck, T. F.; Fisher, B. L.; Mattoo, S.; Remer, L. A.; Slutsker, I.; Zhang, Jianglong

doi:10.5194/acp-2018-468

Cited by 14 publications

(21 citation statements)

References 36 publications

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“…In Figure d, MODIS satellite C6 DT algorithm retrievals of AOD for Borneo on this date show that retrievals were not made in the densest smoke areas, only on the edges or periphery where the AOD is much lower. This suggests that the operational C6 DT algorithm screened these heavy smoke features due to both cloud and a conservative filter that was intended to mask out conditions that are not optimal for retrieving aerosols (Shi et al, ). This type of event led to the development of a new high AOD event DT algorithm that relies in part on the aerosol optical properties that are retrieved from AERONET retrievals during the same event (Shi et al, ).…”

Section: Resultsmentioning

confidence: 99%

“…This suggests that the operational C6 DT algorithm screened these heavy smoke features due to both cloud and a conservative filter that was intended to mask out conditions that are not optimal for retrieving aerosols (Shi et al, ). This type of event led to the development of a new high AOD event DT algorithm that relies in part on the aerosol optical properties that are retrieved from AERONET retrievals during the same event (Shi et al, ). Figure e is the same except for MODIS DB, indicating significantly greater coverage than the DT retrievals of AOD over the land areas in Borneo.…”

Section: Resultsmentioning

confidence: 99%

“…The MODIS DT algorithm does not retrieve any AOD from 5 September through 12 October 2015 (>1 month) corresponding to the period with the consistently highest AOD as measured from AERONET. This is due to multiple reasons: (1) The extremely high aerosol loadings are mistaken as cloud by the low cloud mask, (2) these features are filtered out by inland‐water mask as the retrieving conditions are not optimal, (3) the MODIS DT retrieved AOD are higher than the upper limit of AOD in the algorithm, which is caused by using a too absorbing aerosol model (Shi et al, ). Note that Shi et al () developed an event‐based MODIS DT research algorithm targeting this fire event over Indonesia.…”

Section: Resultsmentioning

confidence: 99%

“…These are the highest AOD ever estimated from AERONET data, and we have no knowledge of smoke AOD values this high having been previously reported in the scientific literature. Retrievals of midvisible AOD from the standard MODIS algorithms (DT, DB, and MAIAC algorithms) consistently underestimated the magnitude of the AOD in the peak burning region (Palangkaraya site) during this event and also did not make retrievals on many high AOD days. However, the special high AOD event algorithm recently introduced and described by Shi et al () overcomes many of these shortcomings in MODIS satellite AOD retrieval for this particular event. Likewise, the new VIIRS DB greatly increases coverage in these heavy‐smoke situations, although the retrievals are inherently more uncertain in such extreme environments. The new hybrid sky radiance scan available only in the new model Cimel Model‐T Sun‐sky radiometers allowed for the retrieval of aerosol refractive indices and size distributions at higher AOD levels due to retrieval capability at smaller SZAs when the 440‐nm signal is not completely attenuated.…”

Section: Discussionmentioning

confidence: 99%

“…Additionally, a new version of the Cimel Sun‐sky radiometer with advanced capability was deployed in two sites impacted by this event: Palangkaraya, Indonesia, (southern Borneo) in one of the major biomass burning source regions and also Singapore, a downwind site ~1,200 km from southern Borneo and ~500 km from southern Sumatra that was heavily impacted by these biomass burning emissions from Indonesia in 2015. We also present some of the standard Moderate Resolution Imaging Spectroradiometer (MODIS) satellite remote sensing retrievals of midvisible AOD during this event, noting that this topic, including recently developed algorithms to measure higher AOD events, are much more thoroughly investigated in other work (Shi et al, ).…”

Section: Introductionmentioning

confidence: 99%

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AERONET Remotely Sensed Measurements and Retrievals of Biomass Burning Aerosol Optical Properties During the 2015 Indonesian Burning Season

et al. 2019

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An extreme biomass burning event occurred in Indonesia from September through October 2015 due to severe drought conditions, partially caused by a major El Niño event, thereby allowing for significant burning of peatland that had been previously drained. This event had the highest sustained aerosol optical depths (AODs) ever monitored by the global Aerosol Robotic Network (AERONET). The newly developed AERONET Version 3 algorithms retain high AOD at the longer wavelengths when associated with high Ångström exponents (AEs), which thereby allowed for measurements of AOD at 675 nm as high as approximately 7, the upper limit of Sun photometry. Measured AEs at the highest monitored AOD levels were subsequently utilized to estimate instantaneous values of AOD at 550 nm in the range of 11 to 13, well beyond the upper measurement limit. Additionally, retrievals of complex refractive indices, size distributions, and single scattering albedos (SSAs) were obtained at much higher AOD levels than possible from almucantar scans due to the ability to perform retrievals at smaller solar zenith angles with new hybrid sky radiance scans. For retrievals made at the highest AOD levels the fine‐mode volume median radii were ~0.25–0.30 micron, which are very large particles for biomass burning. Very high SSA values (~0.975 from 440 to 1,020 nm) are consistent with the domination by smoldering combustion of peat burning. Estimates of the percentage peat contribution to total biomass burning aerosol based on retrieved SSA and laboratory measured peat SSA were ~80–85%, in excellent agreement with independent estimates.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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AERONET Remotely Sensed Measurements and Retrievals of Biomass Burning Aerosol Optical Properties During the 2015 Indonesian Burning Season

et al. 2019

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Connecting Indonesian Fires and Drought With the Type of El Niño and Phase of the Indian Ocean Dipole During 1979–2016

et al. 2018

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This study advances the previous understanding of the role of climate variability on Indonesian fire activity, by considering (i) the presence of different types of El Niño and (ii) the interaction between El Niño and the Indian Ocean Dipole (IOD). We classify 12 El Niño events during 1979-2016 into Eastern Pacific (EP) and Central Pacific (CP) types (four and eight El Niño events, respectively) and analyze observational data of sea surface temperature, precipitation, drought code, biomass burning carbon emission, visibility, and aerosol optical depth accordingly. We find that more intense and prolonged Indonesian drought and fires occur in the EP type, during which the emitted carbon amounts almost double those in the CP type. By further separating the CP type El Niño according to the phase of the IOD, that is, positive and negative, we show that fire seasons with less burning intensity and shorter duration are predominantly associated with weakly positive or even negative phase of the IOD phenomena. Moreover, fire intensity exhibits geographic diversity: fires are always more intensive in southern Kalimantan than in southern Sumatra in all El Niño events, although it is less dry in the former region. The outcome of this study can be applied to drought early warning, fire management, and air quality forecast in Indonesia and adjacent areas by identifying the type of El Niño and the phase of the IOD in advance.Plain Language Summary Indonesian fires are well known for their adverse impact on regional air quality and climate because they release massive amounts of greenhouse gases and aerosols into the atmosphere. This study advances the previous understanding of the role of climate variability on Indonesian fire activity, by considering (i) the presence of different types (or location) of El Niño events in the Pacific Ocean and (ii) the interaction between El Niño and the Indian Ocean Dipole (IOD) phenomena. As a result, we find that more intensive and prolonged Indonesian fires occur during canonical El Niño events when the location of maximum SST anomaly is near the eastern Pacific accompanied with a positive phase of IOD (e.g., in 2006). In contrast, weaker Indonesian drought and fires likely occur in the El Niño events when the location of maximum SST anomaly is near the central Pacific accompanied by a weakly positive or even negative phase of the IOD instead (e.g., in 2009). The outcome of this study can be applied to drought early warning, fire management, and air quality forecast in Indonesia and adjacent areas by identifying the type (or location) of El Niño and the phase (or sign) of IOD in advance. PAN ET AL.7974

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Validation of SOAR VIIRS Over‐Water Aerosol Retrievals and Context Within the Global Satellite Aerosol Data Record

et al. 2018

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This study validates aerosol properties retrieved using a Satellite Ocean Aerosol Retrieval (SOAR) algorithm applied to Visible Infrared Imaging Radiometer Suite (VIIRS) measurements, from Version 1 of the VIIRS Deep Blue data set. SOAR is the over-water complement to the over-land Deep Blue algorithm and has two processing paths: globally, 95% of pixels are processed with the full retrieval algorithm, while the 5% of pixels in shallow or turbid (mostly coastal) waters are processed with a backup algorithm. Aerosol Robotic Network (AERONET) data are used to validate and compare the midvisible (550 nm) aerosol optical depth (AOD), Ångström exponent (AE), and fine mode fraction of AOD at 550 nm (FMF). AOD uncertainty is shown to be approximately ±(0.03 + 10%) for the full and ±(0.03 + 15%) for the backup algorithms, with a small positive median bias around 0.02. When AOD is below about 0.2, the AE and FMF have small negative offsets from AERONET around −0.15 and −0.04, respectively. For higher AOD, AE is less offset and the magnitudes of differences versus AERONET are about ±0.2 and ±0.14, respectively. Aerosol-type classifications provided by SOAR are found to be reasonable, matching optical-based classifications from AERONET over 80% of the time. Spatial and temporal patterns of AOD and AE are also compared with those of other contemporary over-water satellite aerosol data sets; dependent on region, the satellite data sets show varying levels of consistency, with SOAR broadly in-family, and the largest discrepancies in regions with persistent heavy cloud cover.Plain Language Summary Aerosols are small particles in the atmosphere like desert dust, volcanic ash, smoke, industrial haze, and sea spray. Understanding them is important for applications such as hazard avoidance, air quality and human health, and climate studies. Satellite instruments provide an important tool to study aerosol loading over the world. However, individual satellites do not last forever and newer satellites often have improved capabilities compared to older ones. This paper evaluates an extension of an algorithm, originally designed to monitor aerosols from an older satellite instrument, to a new satellite instrument called Visible Infrared Imaging Radiometer Suite. The evaluation is performed by comparing to ground truth data which are part of the National Aeronautics and Space Administration's global Aerosol Robotic Network, as well as to other satellite-based aerosol data sets from different spaceborne instruments.

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Characterizing the 2015 Indonesia Fire Event Using Modified MODIS Aerosol Retrievals

Cited by 14 publications

References 36 publications

AERONET Remotely Sensed Measurements and Retrievals of Biomass Burning Aerosol Optical Properties During the 2015 Indonesian Burning Season

AERONET Remotely Sensed Measurements and Retrievals of Biomass Burning Aerosol Optical Properties During the 2015 Indonesian Burning Season

Connecting Indonesian Fires and Drought With the Type of El Niño and Phase of the Indian Ocean Dipole During 1979–2016

Validation of SOAR VIIRS Over‐Water Aerosol Retrievals and Context Within the Global Satellite Aerosol Data Record

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