Surface-subsurface structural architecture and ground water flow of the Equi Terme hydrothermal area, northern Tuscany Italy
Surface-subsurface structural architecture and ground water flow of the Equi Terme hydrothermal area, northern Tuscany Italy
Italian Journal of Geosciences (October 2015) 134 (3): 442-457
- Apennines
- Apuane Alps
- C-13/C-12
- carbon
- D/H
- Europe
- fault zones
- faults
- geometry
- geophysical methods
- geophysical surveys
- geothermal systems
- ground water
- hot springs
- hydrogen
- hydrogeology
- hydrothermal conditions
- isotope ratios
- isotopes
- Italy
- kinematics
- low temperature
- magnetotelluric methods
- movement
- O-18/O-16
- oxygen
- resistivity
- S-34/S-32
- Southern Europe
- springs
- stable isotopes
- structural analysis
- sulfur
- surveys
- temperature
- thermal waters
- tomography
- Tuscany Italy
- Equi Terme
- Carrara Italy
- Massa Italy
A multidisciplinary integrated approach was used to study the structural architecture influencing the circulation pattern of geothermal fluids in the Equi Terme area (NW Alpi Apuane, Tuscany). Geological-structural surveys were carried out to define the structural setting of the area and to characterize geometries and kinematics of fault systems. Chemical (major components) and isotopic analyses (delta 18O ppm, delta 2H ppm, 3H, delta 13C ppm[DIC], delta 34S ppm[SO4]) were performed on thermal water and cold springs. A geophysical survey was also conducted by means of both Magnetotelluric and Electrical Resistivity Tomography methodologies, in order to gain insight into the resistivity distribution at depth and to indirectly image the subsurface structure. This multidisciplinary approach proved to be a powerful tool, since it unravels the complexity of this natural geothermal system and provides useful suggestion for reconstructing the fluid circulation outflowing at the Equi Terme thermal spring. Results pointed out how the E-W oriented fault system (the Equi Terme Fault) play a key role in controlling the thermal groundwater outflow, and the chemical-physical features of this resource. This structural lineament separates high permeability carbonate complexes (footwall), in which both shallow and deep flow paths develop, from a medium-low permeability succession (hangingwall) that contains evaporitic formations from which thermal water acquires a high salinity and a composition of the Na-Cl (Ca-SO4) type. During the uprising along the fault system, the thermal water is also affected by a mixing with shallow fresh-cold waters that lead to a strong seasonal variation in the chemical-physical properties of the thermal springs.