Reconstructing the Vulcano Island evolution from 3D modeling of magnetic signatures

High-resolution ground and marine magnetic data are exploited for a detailed definition of a 3D model of the
Vulcano Island volcanic complex. The resulting 3D magnetic imaging, obtained by 3-D inverse modeling
technique, has delivered useful constraints both to reconstruct the Vulcano Island evolution and to be used as
input data for volcanic hazard assessment models. Our results constrained the depth and geometry of
the main geo-structural features revealing more subsurface volcanic structures than exposed ones and allowing
to elucidate the relationships between them. The recognition of two different magnetization sectors,
approximatively coincident with the structural depressions of Piano caldera, in the southern half of the island,
and La Fossa caldera at the north, suggests a complex structural and volcanic evolution.Magnetic highs identified
across the southern half of the island reflect the main crystallized feeding systems, intrusions and buried vents,
whose NNW–SSE preferential alignment highlights the role of the NNW–SSE Tindari–Letojanni regional system
from the initial activity of the submarine edifice, to the more recent activity of the Vulcano complex. The low
magnetization area, in the middle part of the islandmay result fromhydrothermally altered rocks. Their presence
not only in the central part of the volcano edifice but also in other peripheral areas, is a sign of a more diffuse
historical hydrothermal activity than in present days. Moreover, the high magnetization heterogeneity within
the upper flanks of La Fossa cone edifice is an imprint of a composite distribution of unaltered and altered
rocks with different mechanical properties, which poses in this area a high risk level for failure processes
especially during volcanic or hydrothermal crisis.

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