Abstract
Aiming at investigating the hydrothermal circulation along the eastern flank of the Vulture volcano, along the outermost edge of the southern Apennine fold-and-thrust belt (ftb), we studied the fossil hydrothermal alteration that mineralized a transtensional fault that crosscuts volcanoclastic rocks in the Rapolla area. On the basis of structural, mineralogical, and fluid inclusion data, three main stages of activity of the hydrothermal system are documented. Stage 1 was produced by the circulation of fluids having low-pH conditions (pH ≈ 3-4) and relatively high-SO42- activity, as testified by the hydrothermal alteration mainly carried out by the alunite group minerals (particularly jarosite), which is typical of an advanced argillic alteration facies. Hydrothermal fluids were characterized by a high temperature of about 200°-210°C. These hot fluids altered and mineralized the matrices of pyroclastic rocks and sealed both burial-related and fault-related fracture networks. Later hydrothermal circulation (Stage 2) was recorded by opal A-rich veins present both within and outside the fault zone. The fluids responsible of opal A precipitation were characterized by lower temperature conditions, probably lower than 100°C. Current goethite mineralization takes place along the main slip surfaces of the study high-angle fault zone due to low temperature (<30°C) underground water circulation. This study highlights that a high-temperature hydrothermal system developed in the past within the transtensional fault zone of the Rapolla area when a high thermal anomaly was present. If we take into account that this area is still affected by a heat flux positive anomaly (90 mW/m2), we may infer that it has the potentiality to be considered an interesting site for future exploration devoted to the finding of medium-enthalpy geothermal resources at depth.
Highlights
Hydrothermal systems cause the redistribution of both energy and mass in response to circulating H2O fluids and form in response to thermal perturbations among which the magma-induced thermal anomalies are the most frequent [1]
We report for the first time evidences of a fossil hightemperature hydrothermal system located along the eastern flanks of the Vulture volcano
Waters circulate within a horst formed by fractured Cretaceous carbonates of the Apulian Platform, located about 15 km East of the study area, sealed by Pleistocene clay. This finding, together with the heat flux anomaly reported for the Vulture area [6], point out the possible presence of a low- to medium-enthalpy geothermal system. The results of this integrated geostructural, mineralogical, and fluid inclusion study take in evidences that hightemperature hydrothermal circulation occurred at quite shallow depths during burial diagenesis of pyroclasts pertaining to the Middle Pleistocene Foggianello and Barile synthems, Vulture volcano, southern Italy
Summary
Hydrothermal systems cause the redistribution of both energy and mass in response to circulating H2O fluids and form in response to thermal perturbations among which the magma-induced thermal anomalies are the most frequent [1]. A hydrothermal system is comprised of the following components: a heat source, a permeable reservoir in which fluids can flush and trigger an active convective circulation, a recharge system, and an impermeable cover, respectively. The rocks affected by a hydrothermal fluid circulation undergo to a variety of alteration processes due to the instability of the primary mineralogical assemblages, which tend to reequilibrate by forming new minerals stable under the new conditions [2]. The different alteration mineralogical assemblages are primarily controlled by the physical-chemical conditions of the hydrothermal fluids.
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