Michele Di Filippo

Detection, forecasting, early warning, and effective monitoring are key aspects for the delimitation of sinkhole-prone areas and for susceptibility assessment and risk mitigation. To attain these goals, direct and indirect techniques can be employed, and the integration of different indirect/non-invasive geophysical methods including 2D- and 3D-electrical resistivity tomography, microgravity, and single-station seismic noise measures was carried out at “Il Piano” (Elba Island – Italy), where at least nine sinkholes occurred between 2008 and 2014. The most likely origin for these sinkholes had been considered related to net erosion of sediment from the alluvium, caused by downward water circulation between the aquifer hosted in the upper layer (Quaternary alluvial deposits) and that in the lower (Triassic brecciated dolomitic limestone and Cretaceous slate). The integrated geophysical survey, therefore, was carried out a) to differentiate shallower from deeper geological layers, b) to detect possible cavities that could evolve into sinkholes, c) to suggest possible triggers, and d) to delimit the sinkhole-prone area. The results of the integrated geophysical surveys suggest that the study area is mainly characterised by paleochannels, and that the sinkhole-prone area boundaries correspond to these paleochannels.

Abstract The Latian volcanoes of Central Italy form several K-rich volcanic districts, some of which are characterized by large volcano-tectonic depressions filled with lakes. The development of these large depressions (>8 km in diameter) occurred from 0.4–0.3 Ma bp , during a climax of regional extension. Analysis of geophysical and deep drilling data and detailed field analysis, allows reconstruction of the evolution of the Bracciano volcanotectonic depression in the Sabatini Volcanic District, northwest of Rome. This depression developed during the Upper Pleistocene inside a NE-trending half-graben structure. The evolution of the half-graben has been driven by NE-trending regional faults which were reactivated during volcanism. Magma rose along these faults and came to rest at 4–7 km depth, probably as a laccolithic body, and was then erupted with emplacement of large volume ignimbrites. A lava plateau recognized by drilling data in the southern and western sectors of the depression is interpreted as being associated with NE-striking swarms of feeder dykes. The final downsagging was caused by NE and NW-trending regional faults after 0.17 Ma. The eastern depression morphology was modified by late Pleistocene N-trending strike-slip faults which were accompanied by intense hydromagmatic activity. Hydromagmatic craters are distinguished in the eastern margin of the area and in the southeastern part of Lake Bracciano in high-frequency seismic sections.

High-resolution multibeam bathymetry was recently collected around Lipari, the largest and most densely populated island of the Aeolian Archipelago (Southern Tyrrhenian Sea). The data were acquired within the context of marine geological studies performed in the area over the last 10 years. We present the first detailed morphological map of the Lipari offshore at 1:100,000 scale (Main Map). A rugged morphology characterizes the submarine portions of Lipari volcano, reflecting both volcanic and erosive-depositional processes. The volcanic features include cones, lava flows and bedrock outcrops. Erosive-depositional features include an insular shelf topped by submarine depositional terraces related to Late-Quaternary sea-level fluctuations, as well as landslide scars, channelized features, fan-shaped deposits and wavy bedforms. The different distribution of volcanic and erosive-depositional features on the various sectors of Lipari is mainly related to the older age of the western flank with respect to the eastern one. The map also provides insights for a first marine geohazard assessment of this active volcanic area.