Your search keyword '"Davide Fronzi"' showing total 5 results

1. The Role of Faults in Groundwater Circulation before and after Seismic Events: Insights from Tracers, Water Isotopes and Geochemistry

Author

Davide Fronzi, Carlo Cardellini, Stefano Caliro, Francesco Mirabella, Costanza Cambi, Daniela Valigi, Stefano Palpacelli, and Alberto Tazioli

Subjects

010504 meteorology & atmospheric sciences, Groundwater flow, Geography, Planning and Development, Geochemistry, Aquatic Science, Fault (geology), 010502 geochemistry & geophysics, 01 natural sciences, Biochemistry, TD201-500, earthquakes, 0105 earth and related environmental sciences, Water Science and Technology, geography, central Italy, Hydrogeology, geography.geographical_feature_category, Water supply for domestic and industrial purposes, isotope hydrology, tracer tests, faults, Groundwater recharge, Hydraulic engineering, Mts. Sibillini, Tectonics, Isotope hydrology, Structural geology, TC1-978, carbonate aquifers, Groundwater, Geology

Abstract

The interaction between fluids and tectonic structures such as fault systems is a much-discussed issue. Many scientific works are aimed at understanding what the role of fault systems in the displacement of deep fluids is, by investigating the interaction between the upper mantle, the lower crustal portion and the upraising of gasses carried by liquids. Many other scientific works try to explore the interaction between the recharge processes, i.e., precipitation, and the fault zones, aiming to recognize the function of the abovementioned structures and their capability to direct groundwater flow towards preferential drainage areas. Understanding the role of faults in the recharge processes of punctual and linear springs, meant as gaining streams, is a key point in hydrogeology, as it is known that faults can act either as flow barriers or as preferential flow paths. In this work an investigation of a fault system located in the Nera River catchment (Italy), based on geo-structural investigations, tracer tests, geochemical and isotopic recharge modelling, allows to identify the role of the normal fault system before and after the 2016–2017 central Italy seismic sequence (Mmax = 6.5). The outcome was achieved by an integrated approach consisting of a structural geology field work, combined with GIS-based analysis, and of a hydrogeological investigation based on artificial tracer tests and geochemical and isotopic analyses.

Published

2021

2. Modelling Shallow Groundwater Evaporation Rates from a Large Tank Experiment

Author

Mattia Gaiolini, Alberto Tazioli, Mirco Marcellini, Stefano Palpacelli, Maria Pia Gervasio, Micòl Mastrocicco, Nicolò Colombani, Davide Fronzi, Colombani, N., Fronzi, D., Palpacelli, S., Gaiolini, M., Gervasio, M. P., Marcellini, M., Mastrocicco, M., and Tazioli, A.

Subjects

Hydrogeology, 010504 meteorology & atmospheric sciences, Water table, Piezometer, Bare soil, Evaporation, 0207 environmental engineering, Soil science, 02 engineering and technology, Groundwater salinity, 01 natural sciences, Numerical model, Salinity, Continuous monitoring, Soil water, Vadose zone, Drawdown (hydrology), Environmental science, 020701 environmental engineering, Groundwater, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering

Abstract

A large tank (1.4 m x 4.0 m x 1.3 m) filled with medium-coarse sand was employed to measure evaporation rates from shallow groundwater at controlled laboratory conditions, to determine drivers and mechanisms. To monitor the groundwater level drawdown 12 piezometers were installed in a semi regular grid and equipped with high precision water level, temperature, and electrical conductivity (EC) probes. In each piezometer, 6 micro sampling ports were installed every 10 cm to capture vertical salinity gradients. Moreover, the soil water content, temperature and EC were measured in the unsaturated zone using TDR probes placed at 5, 20 and 40 cm depth. The monitoring started in February 2020 and lasted for 4 months until the groundwater drawdown became residual. To model the groundwater heads, temperature, and salinity variations SEAWAT 4.0 was employed. The calibrated model was then used to obtain the unknown parameters, such as: maximum evaporation rates (1.5-4.4 mm/d), extinction depth (0.90 m), mineral dissolution (5.0e-9 g/d) and evaporation concentration (0.35 g/L). Despite the drawdown was uniformly distributed, the increase of groundwater salinity was rather uneven, while the temperature increase mimicked the atmospheric temperature increase. The initial groundwater salinity and the small changes in the evaporation rate controlled the evapoconcentration process in groundwater, while the effective porosity was the most sensitive parameter. This study demonstrates that shallow groundwater evaporation from sandy soils can produce homogeneous water table drawdown but appreciable differences in the distribution of groundwater salinity.

Published

2021

3. Comparison between Periodic Tracer Tests and Time-Series Analysis to Assess Mid- and Long-Term Recharge Model Changes Due to Multiple Strong Seismic Events in Carbonate Aquifers

Author

Daniela Valigi, Davide Fronzi, Alberto Tazioli, Sergio Rusi, and Diego Di Curzio

Subjects

lcsh:Hydraulic engineering, 010504 meteorology & atmospheric sciences, Groundwater flow, Sibillini carbonate aquifers, Geography, Planning and Development, Aquifer, Aquatic Science, Fault (geology), 010502 geochemistry & geophysics, 01 natural sciences, Biochemistry, Pore water pressure, lcsh:Water supply for domestic and industrial purposes, Hydraulic conductivity, lcsh:TC1-978, Petrology, earthquakes, 0105 earth and related environmental sciences, Water Science and Technology, geography, lcsh:TD201-500, central Italy, geography.geographical_feature_category, Hydrogeology, tracer tests, Groundwater recharge, time-series analysis, Geology, Groundwater

Abstract

Understanding the groundwater flow in carbonate aquifers represents a challenging aspect in hydrogeology, especially when they have been struck by strong seismic events. It has been proved that large earthquakes change springs hydrodynamic behaviour showing transitory or long-lasting variations and making their management much more difficult. This is the case of Sibillini Massif (central Italy), which has been hit by the well-known 2016&ndash, 2017 seismic period. This work aims to improve the knowledge of carbonate aquifers groundwater circulation and their possible changes in the hydrodynamic behaviour, during and after a series of strong seismic events. The goal has been achieved by comparing long-time tracer tests and transient time-series analysis, based on a sliding-window approach. This approach allowed investigating transient variations in the carbonate aquifers recharge system, highlighting the changes of relationships between the inflow contributions to the spring discharge in the area. As a result, the seismically triggered pore pressure distribution, and the hydraulic conductivity variations, because of the ground shaking and the fault systems activation, account for all the mid- and long-term modifications in the recharge system of Sibillini aquifers, respectively. These outcomes provide valuable insights to the knowledge of aquifer response under similar hydrogeological conditions, that are vital for water management.

Published

2020

4. Evaluating SWAT model performance, considering different soils data input, to quantify actual and future runoff susceptibility in a highly urbanized basin

Author

Micòl Mastrocicco, Nicolò Colombani, Gianluigi Busico, Marco Pellegrini, Davide Fronzi, Alberto Tazioli, Busico, G., Colombani, N., Fronzi, D., Pellegrini, M., Tazioli, A., and Mastrocicco, M.

Subjects

Environmental Engineering, Watershed, Soil and Water Assessment Tool, Runoff, 0208 environmental biotechnology, Reproducibility of Result, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Numerical model, Soil, Streamflow, Water Movements, SWAT model, Extreme event, Waste Management and Disposal, 0105 earth and related environmental sciences, Hydrology, Flood myth, Reproducibility of Results, Water, General Medicine, Models, Theoretical, 020801 environmental engineering, Risk management, Soil water, Environmental science, Surface runoff, Hydrogeological risk, Predictive modelling

Abstract

The Soil and Water Assessment Tool (SWAT) is a physical model designed to predict the hydrological processes that could characterize natural and anthropized watersheds. The model can be forced using input data of climate prediction models, soil characteristics and land use scenarios to forecast their effect on hydrological processes. In this study, the SWAT model has been applied in the Aspio basin, a small watershed, highly anthropized and characterized by a short runoff generation. Three simulations setup, named SL1, SL2 and SL3, were investigated using different soil resolution to identify the best model performance. An increase of space requirement and calibration time has been registered in conjunction with the increasing soil resolution. Among all simulations, SL1 has been chosen as the best one in describing watershed streamflow, despite it was characterized by the lower soil resolution. A map of susceptibility to runoff for the entire basin was so created reclassifying the runoff amount of four years in five classes of susceptibility, from very low to very high. Eleven sub-basins, coinciding with the main urban settlements, were identified as highly susceptible to runoff generation. Considering future climate predictions, a slight increase of runoff has been forecasted during summer and autumn. The map of susceptibility successfully identified as highly prone to runoff those sub-basins where extreme flood events were yet recorded in the past, remarking the reliability of the proposed assessment and suggesting that this methodology could represent a useful tool in flood managing plan.

Published

2020

5. Earthquake-Induced Spring Discharge Modifications: The Pescara di Arquata Spring Reaction to the August–October 2016 Central Italy Earthquakes

Author

Daniela Valigi, Lucia Mastrorillo, Alberto Tazioli, Francesco Mirabella, Costanza Cambi, Giulio Beddini, Davide Fronzi, R. Checcucci, and Carlo Cardellini

Subjects

lcsh:Hydraulic engineering, 010504 meteorology & atmospheric sciences, extensional earthquakes, Geography, Planning and Development, springs, extensional&nbsp, Aquifer, Aquatic Science, 010502 geochemistry & geophysics, 01 natural sciences, Biochemistry, seismic-induced groundwater change, coefficient, recession curve, lcsh:Water supply for domestic and industrial purposes, Hydraulic conductivity, lcsh:TC1-978, hydraulic&nbsp, Spring (hydrology), depletionundefinedcoefficient, change, earthquakes, curve, 0105 earth and related environmental sciences, Water Science and Technology, Hydrology, lcsh:TD201-500, depletion&nbsp, geography, Central Italy, depletion coefficient, geography.geographical_feature_category, seismic‐induced&nbsp, groundwater&nbsp, extensional earthquakes, CentralundefinedItaly, Extensional definition, seismic‐inducedundefinedgroundwaterundefinedchange, recession&nbsp, Italy, recessionundefinedcurve, hydraulicundefinedconductivity, Water chemistry, conductivity, Precipitation index, hydraulic conductivity, Central&nbsp, Geology, Groundwater

Abstract

Co-seismic changes in groundwater regime are often observed after moderate to strong earthquakes. The 24 August 2016 Mw 6.0 extensional Amatrice earthquake, which was the first event of a long-lasting seismic sequence, including the 30 October 2016 Mw 6.5 Norcia event, triggered a significant discharge alteration to the Pescara di Arquata spring, located in the Umbria-Marche Apennines (Northern Apennines, Central Italy) and exploited for drinking purposes. During the first five months after the first mainshock, an extra flow of about 30% was recorded, while both water chemistry and temperature did not show significant changes. Thereafter, the spring discharge decreased significantly, and at the end of 2019 it was still lower than normal. The Standardized Precipitation Index (SPI) indicates that these low mean monthly discharge values are not related to particularly dry conditions. The increase in post-seismic depletion coefficients indicates that the aquifer empties faster than it did during the inter-seismic period. The observed transient increase and subsequent decrease of discharge are consistent with a transient, earthquake-related increase in hydraulic conductivity.

Published

2020