Abstract
In this work, we exploited large DInSAR and GPS datasets to create a 4D image of the magma transfer processes at Mauna Loa Volcano (Island of Hawai’i) from 2005 to 2015. The datasets consist of 23 continuous GPS time series and 307 SAR images acquired from ascending and descending orbits by ENVISAT (ENV) and COSMO-SkyMed (CSK) satellites. Our results highlight how the joint use of SAR data acquired from different orbits (thus with different look angles and wavelengths), together with deformation data from GPS networks and geological information can significantly improve the constraints on the geometry and location of the sources responsible for the observed deformation. The analysis of these datasets has been performed by using an innovative method that allows building a complex source configuration. The results suggest that the deformation pattern observed from 2005 to 2015 has been controlled by three deformation sources: the ascent of magma along a conduit, the opening of a dike and the slip along the basal decollement. This confirms that the intrusion of the magma within a tabular system (rift dikes) may trigger the sliding of the SE portion of the volcanic edifice along the basal decollement. This case study confirms that it is now possible to exploit large geodetic datasets to improve our knowledge of volcano dynamics. The same approach could also be easily applied in other geodynamical contexts such as geothermal reservoirs and regions with complex tectonics.
Highlights
Earth Sciences have experienced in the last decades a significant growth of in situ and remote sensing measurements useful for understanding the ongoing natural and anthropogenic phenomena
The slip along the basal decollement is represented by the arrows, proportional to the slip magnitude
Previous studies on ground deformation at Mauna Loa focused on the nature of the magmatic feeding system of the volcano or on the interaction between the magmatic system and the basal decollement [11,15,21,28,38]
Summary
Earth Sciences have experienced in the last decades a significant growth of in situ and remote sensing measurements useful for understanding the ongoing natural and anthropogenic phenomena. Iris.edu) data archives, as well as large remote sensing data archives The availability of Earth Sciences large dataset has produced an imbalance between the data production and their effective exploitation in research activities. This is crucial in the Earth Sciences, where the partial use of the available information for a specific area implies a partial understanding of the observed phenomena since the available data monitor different effects of the same phenomena. During a volcanic eruption, it is possible to collect several kinds of data [1] (e.g., gas emissions, ground displacements, seismic tremor, etc.), all of them describing a particular aspect of the same phenomenon
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