2020
DOI: 10.3390/rs12050820
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Volcanic Hot-Spot Detection Using SENTINEL-2: A Comparison with MODIS–MIROVA Thermal Data Series

Abstract: In the satellite thermal remote sensing, the new generation of sensors with high-spatial resolution SWIR data open the door to an improved constraining of thermal phenomena related to volcanic processes, with strong implications for monitoring applications. In this paper, we describe a new hot-spot detection algorithm developed for SENTINEL-2/MSI data that combines spectral indices on the SWIR bands 8a-11-12 (with a 20-meter resolution) with a spatial and statistical analysis on clusters of alerted pixels. The… Show more

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Cited by 39 publications
(34 citation statements)
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References 62 publications
(107 reference statements)
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“…This seismic gap may represent the region of persistent partial melt (i.e., Hudson et al, 2017) that connects the volcano to its deeper plumbing system, and/or has heated nearby country rock resulting in ductile rock behavior for extended time periods in otherwise brittle crust (Castaldo et al, 2019;Parisio et al, 2019). Indeed, renewed and persistent volcanic activity at Oldoinyo Lengai since late 2018, as inferred from satellite data (Massimetti et al, 2020), require open conduits transporting volatiles and melt to the surface. From tomography and complementary receiver function studies (Plasman et al, 2017), the volcano is underlain by a low S-wave anomaly and high Vp/Vs ratios at 5 km depth, which continue well under the rift shoulder (Roecker et al, 2017) and may represent zones of partial melt below the volcano.…”
Section: Plumbing Systemmentioning
confidence: 99%
“…This seismic gap may represent the region of persistent partial melt (i.e., Hudson et al, 2017) that connects the volcano to its deeper plumbing system, and/or has heated nearby country rock resulting in ductile rock behavior for extended time periods in otherwise brittle crust (Castaldo et al, 2019;Parisio et al, 2019). Indeed, renewed and persistent volcanic activity at Oldoinyo Lengai since late 2018, as inferred from satellite data (Massimetti et al, 2020), require open conduits transporting volatiles and melt to the surface. From tomography and complementary receiver function studies (Plasman et al, 2017), the volcano is underlain by a low S-wave anomaly and high Vp/Vs ratios at 5 km depth, which continue well under the rift shoulder (Roecker et al, 2017) and may represent zones of partial melt below the volcano.…”
Section: Plumbing Systemmentioning
confidence: 99%
“…MODIS infrared data have a 1 km spatial resolution and a high revisit frequency (up to four times daily) for volcanic monitoring purposes. Highspatial resolution thermal satellite datasets, including S2 and L8, have been investigated by applying a novel hotspot detection algorithm based on fixed ratios in the shortwave infrared (SWIR) regions with a contextual threshold derived from a statistical distribution of hotspot pixel clusters (Massimetti et al, 2020), as SWIR signals, in particular, record almost purely thermal emissions produced by hot emitting bodies (Blackett, 2017). Images were analyzed considering the SWIR top-of-atmosphere (TOA) reflectances in the ρ12 (2.19 µm), ρ11 (1.61 µm), and ρ8A (0.86 µm) bands for the S2 MSI and the ρ7 (2.11-2.29 µm), ρ6 (1.57-1.65 µm), and ρ5 (0.85-0.88 µm) bands for the L8 OLI.…”
Section: Thermal Infrared Data and Determination Of Migrating Temperature Anomaliesmentioning
confidence: 99%
“…Remote sensing is an efficient and safe method for monitoring the evolution of a volcano; effective observation techniques include thermal remote sensing (Coppola et al, 2020), synthetic aperture radar (SAR) analysis from spaceborne or airborne platforms (Schaefer et al, 2016), and multisensor approaches (Corradini et al, 2016). Freely available satellite data and smart data science allow the monitoring of deformation fields, thermal anomalies, and gas emissions in near real time (e.g., Valade et al, 2019;Massimetti et al, 2020). In this study, we use a multisensor remote sensing approach to investigate Shiveluch, one of the most active volcanoes in Kamchatka (Figures 1A,B).…”
Section: Introductionmentioning
confidence: 99%
“…All these locations were a part of the sample training dataset, comprising of 10,800 training points across the Australian mainland. The fire locations were visually verified from active fire alerts calculated from the Sentinel-2 data, as this can successfully recognize thermal trends [37]. The highlighted hot spots were calculated using short-wave infrared (SWIR-Band 12) with near infrared wavelengths (NIR-Band 5) and stress burned areas and a wider range of short-wave infrared wavelengths providing more purified hotspot detection [38].…”
Section: Fire Occurrence Locationmentioning
confidence: 99%