Improved detection of airborne volcanic ash using multispectral infrared satellite data

Ellrod, Gary P.; Connell, Bernadette H.; Hillger, Donald W.

doi:10.1029/2002jd002802

Cited by 100 publications

(67 citation statements)

References 26 publications

(31 reference statements)

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“…The net effect of these improvements will be to reliably sense more of each ash cloud, and to sense the ash clouds to a greater distance and time from their source. In addition, the availability of a 3.7 µm channel on MTSAT will enable implementation of 3-channel techniques (Ellrod et al, 2003) to better detect volcanic clouds, as well as further research into improved uses of short-wave IR channels for future satellite sensors.…”

Section: Future Improvements In Ir Detectionmentioning

confidence: 99%

An evaluation of volcanic cloud detection techniques during recent significant eruptions in the western ‘Ring of Fire’

Tupper

Carn

Davey

et al. 2004

Remote Sensing of Environment

108

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We examined recent volcanic cloud events in the Western Pacific and Indonesian area, to validate the performance of remote sensing techniques used to support the International Airways Volcano Watch (IAVW). Five events were considered, during which eruptions from eight volcanoes injected ash into the upper troposphere or lower stratosphere. For one of the eruptions, at Miyakejima, Japan, at least five aircraft encountered volcanic ash clouds, and the cost to three operators alone exceeded US $12,000,000 in aircraft repairs, diversions, and lost operating time. We performed 'reverse' absorption and 'pattern analysis' using GMS-5/VISSR, MODIS and AVHRR data, and we examined TOMS SO 2 and Aerosol Index data, surface-based observations, pilot reports, and dispersion model output. Our results verify that the introduction of 'reverse' absorption using the geostationary GMS-5 platform significantly enhanced our capacity to monitor volcanic ash clouds in the region. In one case, we tracked an eruption cloud for approximately 80 hours. The primary impediment to remote monitoring is the presence of overlying cloud, or substantial amounts of ice within the volcanic clouds. TOMS data showed success in identifying volcanic clouds during these conditions, but was limited by the infrequency of observations. More effective future operation of the IAVW relies on developing complementary methods of volcanic cloud remote sensing, and greatly increasing the amount and quality of available surface and air observations, including observations of precursor activity. An understanding of the likely future limitations of remote sensing techniques will aid in the refining of IAVW procedures.

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Section: Future Improvements In Ir Detectionmentioning

confidence: 99%

An evaluation of volcanic cloud detection techniques during recent significant eruptions in the western ‘Ring of Fire’

Tupper

Carn

Davey

et al. 2004

Remote Sensing of Environment

108

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“…The local variation index T11-T12 (x, y, t) takes into account the reverse absorption of volcanic ash clouds at spectral wavelengths of 11 mm and 12 mm in comparison with meteorological ones (Prata 1989a, b). The local variation index T3-T11 (x, y, t), instead, considers the potential of the different behaviour in the mid-infrared band (MIR) of weather clouds and ash plumes (Ellrod et al 1999(Ellrod et al , 2003, contributing to better ash particle identification and discrimination. Negative values of the T11-T12 (x, y, t) index are generally expected in the presence of volcanic ash, whereas positive values of the T3-T11 (x, y, t) should characterize the same features with a different intensity, on the basis of the observational conditions .…”

Section: Rst Ash Techniquementioning

confidence: 99%

“…However, these traditional satellite techniques, although performing quite well under specific conditions (e.g. low water vapour or ice concentration inside the plume, suitable temperature contrast between surface background and ash clouds), generally show unstable behaviour, with performances depending on local conditions as well as on the nature and features of erupted ash clouds (Ellrod and Connel 1999, Simpson et al 2000, Prata et al 2001, Simpson et al 2001, Ellrod et al 2003.…”

Section: Introductionmentioning

confidence: 99%

“…Ellrod and Connel 1999, Ellrod et al 2003, Bonfiglio et al 2005, Pavolonis et al 2006, although satellite methods capable of automatically identifying volcanic ash clouds under different observational conditions, assuring a full reliability (i.e. ash detection with very low false positive rate), are still required for effective monitoring of such volcanic phenomena.…”

Section: Introductionmentioning

confidence: 99%

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Assessment and validation in time domain of a Robust Satellite Technique (RST_ASH) for ash cloud detection

Marchese

Filizzola

Mazzeo

et al. 2011

Geomatics, Natural Hazards and Risk

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The Robust Satellite Technique (RST) approach is a general scheme of satellite data analysis used to study several natural and environmental hazards. In this paper, the results of a long-term time domain analysis, performed on its RST ASH configuration, specifically tailored to detect and track volcanic ash clouds, are presented. One year of satellite sub-scenes provided by the Advanced Very High Resolution Radiometer (AVHRR), covering an area of about 90 000 km 2 around Mt Etna volcano (Italy), was analysed in order to assess RST ASH performances in periods of ash emissions, as well as during unperturbed conditions (i.e. no ash events). The results and limits of such an approach are discussed, together with possible further improvements achievable by its implementation to different satellite sensor data, e.g. EOS-MODIS and MSG-SEVIRI.

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“…Because of the sporadic nature of volcanic eruptions and their large geographic extents, satellite remote sensing provides the most suitable technique for detecting and assessing volcanic emissions. The detection and assessment of volcanic ash clouds has been performed using different multispectral polar satellite instruments, including the Advanced Very High Resolution Radiometer (AVHRR, Prata, 1989a, b;Wen and Rose, 1994;Krotkov et al, 1999;Yu et al, 2002;Corradini et al, 2010), the Moderate Resolution Imaging Spectroradiometer (MODIS, Hillger at al., 2002;Ellrod et al, 2003;Watson et al, 2004;Corradini et al, 2008Corradini et al, , 2009Corradini et al, , 2010 aboard the Terra/Aqua NASA satellites, and multispectral geostationary satellite systems like for example the Geostationary Operational Environmental Satellite (GOES, Rose and Mayberry, 2000;Yu et al, 2002;Ellrod et al, 2003) and the Spinning Enhanced Visible and Infrared Imager radiometer (SEVIRI, Prata and Kerkmann, 2007) on board Meteosat Second Generation (MSG) satellites.…”

mentioning

confidence: 99%

A new simplified approach for simultaneous retrieval of SO<sub>2</sub> and ash content of tropospheric volcanic clouds: an application to the Mt Etna volcano

et al. 2013

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Abstract. A new procedure is presented for simultaneous estimation of SO2 and ash abundance in a volcanic plume, using thermal infrared (TIR) MODIS data. Plume altitude and temperature are the only two input parameters required to run the procedure, while surface emissivity, temperature, atmospheric profiles, ash optical properties, and radiative transfer models are not necessary to perform the atmospheric corrections. The procedure gives the most reliable results when the surface under the plume is uniform, for example above the ocean, but still produces fairly good estimates in more challenging and not easily modelled conditions, such as above land or meteorological cloud layers. The developed approach was tested on the Etna volcano. By linearly interpolating the radiances surrounding a detected volcanic plume, the volcanic plume removal (VPR) procedure described here computes the radiances that would have been measured by the sensor in the absence of a plume, and reconstructs a new image without plume. The new image and the original data allow computation of plume transmittance in the TIR-MODIS bands 29, 31, and 32 (8.6, 11.0 and 12.0 μm) by applying a simplified model consisting of a uniform plume at a fixed altitude and temperature. The transmittances are then refined with a polynomial relationship obtained by means of MODTRAN simulations adapted for the geographical region, ash type, and atmospheric profiles. Bands 31 and 32 are SO2 transparent and, from their transmittances, the effective ash particle radius (Re), and aerosol optical depth at 550 nm (AOD550) are computed. A simple relation between the ash transmittances of bands 31 and 29 is demonstrated and used for SO2 columnar content (cs) estimation. Comparing the results of the VPR procedure with MODTRAN simulations for more than 200 000 different cases, the frequency distribution of the differences shows the following: the Re error is less than ±0.5 μm in more than 60% of cases; the AOD550 error is less than ±0.125 in 80% of cases; the cs error is less than ±0.5 g m−2 in more than 60% of considered cases. The VPR procedure was applied in two case studies of recent eruptions occurring at the Mt Etna volcano, Italy, and successfully compared with the results obtained from the established SO2 and ash assessments based on look-up tables (LUTs). Assessment of the sensitivity to the plume altitude uncertainty is also made. The VPR procedure is simple, extremely fast, and can be adapted to other ash types and different volcanoes.

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Improved detection of airborne volcanic ash using multispectral infrared satellite data

Cited by 100 publications

References 26 publications

An evaluation of volcanic cloud detection techniques during recent significant eruptions in the western ‘Ring of Fire’

An evaluation of volcanic cloud detection techniques during recent significant eruptions in the western ‘Ring of Fire’

Assessment and validation in time domain of a Robust Satellite Technique (RST_ASH) for ash cloud detection

A new simplified approach for simultaneous retrieval of SO<sub>2</sub> and ash content of tropospheric volcanic clouds: an application to the Mt Etna volcano

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Improved detection of airborne volcanic ash using multispectral infrared satellite data

Cited by 100 publications

References 26 publications

An evaluation of volcanic cloud detection techniques during recent significant eruptions in the western ‘Ring of Fire’

An evaluation of volcanic cloud detection techniques during recent significant eruptions in the western ‘Ring of Fire’

Assessment and validation in time domain of a Robust Satellite Technique (RSTASH) for ash cloud detection

A new simplified approach for simultaneous retrieval of SO&lt;sub&gt;2&lt;/sub&gt; and ash content of tropospheric volcanic clouds: an application to the Mt Etna volcano

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Assessment and validation in time domain of a Robust Satellite Technique (RST_ASH) for ash cloud detection

A new simplified approach for simultaneous retrieval of SO<sub>2</sub> and ash content of tropospheric volcanic clouds: an application to the Mt Etna volcano