Abstract

Finding the geometry of aquifers in an active volcano is important for evaluating the hazards associated with phreato‐magmatic phenomena and incidentally to address the problem of water supply. A combination of electrical resistivity tomography (ERT), self‐potential, CO 2 , and temperature measurements provides insights about the location and pattern of ground water flow at Stromboli volcano. The measurements were conducted along a NE‐SW profile across the island from Scari to Ginostra, crossing the summit (Pizzo) area. ERT data (electrode spacing 20 m, depth of penetration of ∼200 m) shows the shallow architecture through the distribution of the resistivities. The hydrothermal system is characterized by low values of the resistivity (<50 Ω m) while the surrounding rocks are resistive (>2000 Ω m) except on the North‐East flank of the volcano where a cold aquifer is detected at a depth of ∼80 m (resistivity in the range 70–300 Ω m). CO 2 and temperature measurements corroborate the delineation of the hydrothermal body in the summit part of the volcano while a negative self‐potential anomaly underlines the position of the cold aquifer.