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Article

Joint Interpretation of Geophysical Results and Geological Observations for Detecting Buried Active Faults: The Case of the “Il Lago” Plain (Pettoranello del Molise, Italy)

by
Rosa Nappi
1,
Valeria Paoletti
2,*,
Donato D’Antonio
3,
Francesco Soldovieri
4,
Luigi Capozzoli
4,5,
Giovanni Ludeno
4,
Sabina Porfido
1,6 and
Alessandro Maria Michetti
7
1
Istituto Nazionale di Geofisica e Vulcanologia, Sezione di Napoli Osservatorio Vesuviano, Via Diocleziano 328, 80124 Naples, Italy
2
Department of Earth, Environment and Resources Science, University Federico II, Complesso di Monte S. Angelo, Via Cintia, Edifice L, 80126 Naples, Italy
3
Geophysical consultant, Vicolo III San Nicola, 2, 86013 Gambatesa, Italy
4
Institute for Electromagnetic Sensing of the Environment, National Research Council, Via Diocleziano 328, 80124 Naples, Italy
5
Institute of Methodologies for Environmental Analysis, National Research Council, C.da S. Loja-Zona Industriale, 85050 Tito Scalo, Italy
6
Consiglio Nazionale delle Ricerche—Isa, Via Roma 64, 83100 Avellino, Italy
7
Dipartimento di Scienza e Alta Tecnologia, Università degli Studi dell’Insubria, Via Valleggio, 11, 22100 Como, Italy
*
Author to whom correspondence should be addressed.
Remote Sens. 2021, 13(8), 1555; https://doi.org/10.3390/rs13081555
Submission received: 24 February 2021 / Revised: 13 April 2021 / Accepted: 14 April 2021 / Published: 17 April 2021

Abstract

:
We report a geophysical study across an active normal fault in the Southern Apennines. The surveyed area is the “Il Lago” Plain (Pettoranello del Molise), at the foot of Mt. Patalecchia (Molise Apennines, Southern Italy), a small tectonic basin filled by Holocene deposits located at the NW termination of the major Quaternary Bojano basin structure. This basin, on the NE flank of the Matese Massif, was the epicentral area of the very strong 26 July, 1805, Sant’Anna earthquake (I0 = X MCS, Mw = 6.7). The “Il Lago” Plain is bordered by a portion of the right-stepping normal fault system bounding the whole Bojano Quaternary basin (28 km long). The seismic source responsible for the 1805 earthquake is regarded as one of the most hazardous structures of the Apennines; however, the position of its NW boundary of this seismic source is debated. Geological, geomorphological and macroseismic data show that some coseismic surface faulting also occurred in correspondence with the border fault of the “Il Lago” Plain. The study of the “Il Lago” Plain subsurface might help to constrain the NW segment boundary of the 1805 seismogenic source, suggesting that it is possibly a capable fault, source for moderate (Mw < 5.5) to strong earthquakes (Mw ≥ 5.5). Therefore, we constrained the geometry of the fault beneath the plain using low-frequency Ground Penetrating Radar (GPR) data supported by seismic tomography. Seismic tomography yielded preliminary information on the subsurface structures and the dielectric permittivity of the subsoil. A set of GPR parallel profiles allowed a quick and high-resolution characterization of the lateral extension of the fault, and of its geometry at depth. The result of our study demonstrates the optimal potential of combined seismic and deep GPR surveys for investigating the geometry of buried active normal faults. Moreover, our study could be used for identifying suitable sites for paleoseismic analyses, where record of earthquake surface faulting might be preserved in Holocene lacustrine sedimentary deposits. The present case demonstrates the possibility to detect with high accuracy the complexity of a fault-zone within a basin, inferred by GPR data, not only in its shallower part, but also down to about 100 m depth.

1. Introduction

Only limited portions of active brittle fault zones are exposed at the surface, due to the combination of limited tectonic rock exhumation and erosion [1]. In particular, active normal faults typically trigger rapid feedback response of surface processes, such as gravitational instability and erosional dismantling of the uplifted footwall blocks, coupled with enhanced sedimentation in the downthrown hanging wall counterpart (e.g., [1,2,3,4]). In the Southern Apennines of Italy, tectonically active extensional structures are characterized by low strain-rates and a tectonic architecture (e.g., [5,6,7] and reference therein) inherited from previous phases of shortening. Here, the identification and characterization of active faults is not always straightforward. Moreover, the distributed deformation on segmented normal fault-systems and the presence of thick clastic covers may mask important details of the active fault structure, making it difficult to correctly interpret the signature of recent faulting (e.g., [5,8,9]). For these reasons, a geological approach based on traditional geomorphic and structural observations should be assisted by geophysical investigation, which can provide effective insight for the characterization of active faults segments. Geophysical active and passive methods can indeed yield important information on the subsoil characteristics and/or rupture planes geometry (e.g., [10,11,12,13,14]).
In this paper, we present the results of a relevant case-history, with the recent geophysical survey performed by seismic refraction tomography and Ground Penetrating Radar (GPR) to characterize the active buried fault bordering the western edge of the “Il Lago” Plain (Pettoranello del Molise), at the foot of Mt. Patalecchia (Molise Apennines, Southern Italy; Figure 1). The survey area, “Il Lago” is a small endoreic basin that closes the structure of the NW-SE Quaternary Bojano basin towards NW. The plain is bordered by a portion of the 28 km long, right-stepping normal fault system bounding the whole Bojano Quaternary basin. This fault system is considered one of the most seismically hazardous structure of the Apennines [15,16]. The whole region is one of the most seismically active areas of the Southern Apennines repeatedly hit during the last centuries by destructive earthquakes: the 5 December, 1456 earthquake (I = XI MCS; Mw = 7.2; [17,18]); the 5 June, 1688 earthquake (I = XI MCS, Mw = 7.1; [18,19]); and the S. Anna earthquake of 26 July, 1805 (I = X MCS, Mw = 6.7; [18,20] Figure 1) whose epicentral area was the Bojano basin. This strong historical seismicity was characterized not only by a high and extensive level of damage, but also by widespread, both primary and secondary, environmental effects [20,21,22]. According to DISS database, the “Il Lago” Plain is located between two well-known seismogenic sources: Carpino-Le Piane to the NW and Bojano to the SE [23].
The structural, geomorphological and macroseismic data suggest [21,22,25,26] that the Quaternary normal fault segments in the Bojano area correspond to a system of capable faults (i.e., faults that can produce deformation and dislocation at the surface during strong seismic events) comparable to the systems responsible for the great recent earthquakes in the Apennines (e.g., Fucino 1915, Irpinia 1980, Amatrice Visso-Norcia 2016–2017).
Detailed studies on environmental effects generated by the strong 1805 earthquake [19,21,22] showed that some coseismic surface faulting might have also occurred in correspondence with the “Il Lago” Plain. The normal fault bordering the plain to the SW is a poorly known structure, weakly expressed at the surface by small morphological scarps/warps (Figure 2). Indeed, some difficulties persist in defining the detailed faulting geometry (both at the surface and at depth) and type of the structures related to the 1805 earthquake. The only available information about the northern part of the 1805 seismic source derives from sparse paleosismological evidence [15,27].
Therefore, the “Il Lago” Plain, filled with young sediments that might preserve evidence related to Holocene surface faulting events, is a key location for understanding the seismic potential of the area. In this line, we investigated the subsurface of the northern portion of the 1805 fault system, bordering the “Il Lago” Plain, using low-frequency Ground Penetrating Radar (GPR) data supported by seismic tomography data. Seismic data yielded preliminary information on the underground structures and the dielectric permittivity of the subsoil. GPR data allowed a quick and detailed characterization of the fault geometry, with enhanced depth penetration and lateral resolution.

2. Geological and Seismological Context

2.1. Regional Setting

The tectonics of the Italian peninsula is driven by the Neogene–Quaternary kinematic evolution of the Mediterranean area. Since the Early-Middle Pleistocene, a severe (~7 mm/year) regional uplift coupled to a predominant NE–SW extension affected the inner sectors of the Southern Apennines [28,29]. NW-striking normal faults, which are parallel to the chain axis, developed in response to this extension. Active crustal extension is also expressed by focal mechanisms of strong earthquakes and geodetic data ([30,31,32] and references therein). The normal faults network dissecting the Southern Apennines axis consist of 5–10 km long, mostly NW-trending and NE-dipping, individual segments, forming complex systems up to 25–30 km long (e.g., [15,33] and references therein). Most of them show clear hints of activity, such as the offset of Quaternary continental deposits and the fresh exposure of bedrock fault planes. This was interpreted as mostly due to rapid exhumation during coseismic surface slip episodes occurred after the Last Glacial Maximum [34,35].
The Molise Apennines are characterized by a series of intermountain basins, of which the most northerly ones are the Isernia and Bojano basins (Figure 1). The evolution of these basins, starting at least from the Middle Pleistocene, was controlled by the NE–SW crustal extension [36,37,38], along a segmented system of active normal faults [15,16,33]. Similar to the normal fault segments that generated the 23 November 1980, Irpinia-Lucania earthquake, the Molise Apennines intermountain basins developed along a highly segmented fault array formed by N- to NE-dipping active normal faults [15,16].

2.2. The Bojano Basin Fault-System

The above-mentioned tectonic regime favored the progressive development of fault slopes, well represented along the SW edge of the Bojano basin. The fault system of the “Bojano basin” consists of NW–SE normal synthetic and antithetic fault segments. They outcrop along the Matese Massif slopes and are also buried at the edges of the plain [21,27,34,35]. The buried faults acted as the main structure in the most ancient phases of the tectonic-sedimentary evolution of the area, causing the early phase of the Bojano basin opening and later transferring the tectonic activity to the piedmont faults. The NE-dipping system fault consists of five main segments ranging from 4 to 7 km for a total length of about 28 km (e.g., [15,16]). It includes the northeastern side of Mt. Patalecchia, the sector near the town of Cantalupo del Sannio, and the area between the towns of Bojano and Campochiaro (Figure 1). The outcropping Meso-Cenozoic bedrock is attributable to a depositional environment of carbonate platform/ramp and transition basin. It deposited in a stratigraphic interval ranging, in the study area, from the Upper Jurassic to the Middle Miocene. This is followed by calcareous-marly sediments of a neritic environment and by the calcarenitic-clayey-arenaceous sequences of foredeep from the Upper Tortonian to the Lower Messinian. The study area was involved in tertiary compressive deformation since the Upper Miocene; the folds and thrusts deriving from this tectonic phase were also subsequently displaced by strike–slip transfer faults. The present structural setting sees the carbonate bedrock sequence strongly dissected by variously oriented faults (N–S, E–W, NE–SW). These were superimposed by normal faults with an Apennine orientation (NW–SE), which are the result of the Quaternary and ongoing crustal extension. They may reactivate the discontinuities inherited from the previous tectonic phase. Long-term Quaternary normal displacement in the central part of these NE-dipping fault segments is up to 900 m, while Late Pleistocene to Holocene slip-rates have been estimated in 0.1 to 1.0 mm/year [15,16,27].
The study area, the “Il Lago” Plain, is a minor local basin that closes towards NW the Bojano basin and is bordered by a buried active normal fault that is part of the Mt. Patalecchia Fault System (MPFS) ([39] and references therein) [40] (Figure 1). The total offset along the MPFS is at least 400 m [41]. The “Il Lago” area owes its name to a natural event that occurred during the 17th century, when the stream crossing it formed the lake. The final drainage of the plain was carried out in 1813 A.D. [42].
The Bojano basin, and its continuation towards the minor local “Il Lago” Plain, are filled by the Middle Pleistocene–Holocene slope-derived breccias, colluvial, fluvio-lacustrine and alluvial fan deposits [43,44,45]. The thickness of these successions reaches about 400 m in some sectors of the Bojano basin [46] and is not homogeneous within the basin due to an irregular trend of pre-Quaternary bedrock paleo-topography.
While for the Bojano basin a detailed stratigraphy is available, and the Middle to Late Pleistocene age of the fluvial-marshy and lacustrine-palustrine infilling is constrained based on borehole analyses and radiometric dating of tephra [15,47,48], for the “Il Lago” Plain, there is no published information on the sediments filling the recent plain. The Mt. Patalecchia mountainside is mainly constituted by Mesozoic calcareous successions, while in the foothills, the Cenozoic calcareous deposits crop up, composing the substratum of the lacustrine deposits of the “Il Lago” Plain (Figure 2).

2.3. Paleoseismicity and Historical Seismicity

The evidence of Quaternary activity along the “Il Lago” fault segment was documented by the offset of Holocene alluvial deposits inside a paleoseismic trench, with evidence of at least two surface-rupturing seismic events occurred during the last 2600 years on the normal fault bordering the north-eastern slope of Mt. Patalecchia [27]. More specifically, the authors dated these two events between 3130 ± 70 and 2590 ± 50 years B.P.
Another strong seismic event dated to the early 3rd century B.C. (i.e., ~280 B.C.) was identified by archaeoseismological evidence observed SE of the Bojano basin, along the Campochiaro fault (Figure 1) [50].
As mentioned, in historical times, the Bojano basin was the epicentral area of several high-magnitude seismic events: in 1456 [17,18] and in 1805 [18]) (Figure 1).
The December 1456 earthquakes (on the 5th and 30th), according to the authors of [48] causing at least 60,000 casualties, were certainly among the most catastrophic and powerful earthquakes occurred in Italy. Such earthquakes are related to either three or five different seismogenic sources located in a wide area spanning from the central to the Southern Apennines, with one of the sources located to the north of the Matese ridge [17,51,52]. The 1456 earthquake Imax reached the XI degree of the MCS scale (Mw = 7.2 [24]). Even though there is no historical description of the surface expression of the faults related to the 1456 earthquake, secondary ground effects (e.g., landslides, hydrological variations, fractures, liquefaction phenomena mostly related to ground shaking) were documented. Furthermore, the seismic sequence triggered a moderate tsunami in the harbor of Naples where some ships were damaged [53].
The 26 July, 1805 earthquake, known as the “St. Anna’s earthquake”, was another energetic and destructive historical event that struck the Bojano basin causing about 5000 causalities [20] (Figure 1). It was felt in the Molise and Campania regions, in more than 200 localities, with I0 = X MCS and Mw = 6.7 [24] reaching its maximum intensity, Imax = XI MCS in Frosolone [20], nearly 20 km to the E of the town of Isernia, whose level of damage reached the X MCS. Unlike the 1456 earthquake, several primary coseismic effects on the natural environment were identified for the 1805 earthquake, based on the review of historical documents. Since these effects are particularly relevant for the present study, we describe them in detail in the next section.
Apart from the seismic events of 1805, this area was affected by low-magnitude, background, seismicity characterized by both sparse earthquakes and seismic sequences [54,55,56], such as the event of 1882 (with epicentral location in the Isernia area, I0 = VII (Mw = 5.2, [24]).
In the last decades, the instrumental seismicity of the Northern Matese area was characterized by low-energy swarms and sparse seismic events with maximum magnitudes of 4.0 < Ml < 5.0 [54,55,57,58,59,60]. The last earthquake of the area occurred on 16 January 2016 with Ml 4.1, affecting an area located ~10 km NE of the Bojano basin (Figure 1).

2.4. Environmental Effects of the 1805 S. Anna’s Earthquake

A detailed description of ground ruptures is reported in historical documents regarding the destructive 1805 earthquake [60,61,62,63,64,65]. Primary effects such as surface faulting, and secondary effects including hydrological anomalies, ground cracks, slope movements, ground settlements and tsunamis were observed [20,21,22,25,26,66,67,68,69] (Table 1 and Figure 1).
Surface ruptures were reconstructed along the synthetic normal faults bordering the Mt. Patalecchia fault segment [21]. Based on the isoseismal intensity distribution, environmental effects and paleoseismological data, some authors associated the 1805 earthquake to a seismogenic source located in the Bojano basin [21,25,38,66,69,70,71].
Most ground effects were located within the VIII MCS isoseismal area [20] (Figure 1). About 100 seismically induced environmental effects allowed assessment of an intensity value (I = VX) for 50 municipalities located in the near and far field area [26]. Based on the review of historical documents, and in agreement with geological investigations along the Bojano fault system [25,27,66], it was possible to measure the surface rupture length (40 km) according to the methodology proposed in [56,72,73] (and references therein). The length of the “macroseismic” surface faulting was estimated after joining the precise locations of fault ruptures corresponding to the end-to-end distance between the farthest locality points where fault ruptures were reported. In fact, several authors contemporary to the earthquakes [61,63,64,65] described extensive ground ruptures with vertical displacements up to 1–1.5 m, in at least two localities, Morcone (Benevento district) and Guardiaregia (Isernia district; Figure 1), likely due to movements along a Holocene normal fault on the NE slopes of the Matese Massif [15,16,21,22,26]. The secondary effects triggered by the earthquake were: at least 26 landslides, mainly rock falls, topples, slumps, earth flows, and slump earth flows, and hydrological anomalies in 29 localities, mainly around Bojano (Biferno springs) and Mt. Matese. It is important to note the distribution of landslides vs. the earthquake fault: most of the landslides (88.5%) occurred within a distance of 30 km; the rest of them took place within a distance of about 80 km; in particular, 23.0% of the total occurred in the epicentral area (0–10 km), distributed along the zone of coseismic faulting, and 65% were between 10 and 30 km. Most landslides concentrated inside the intensity VIIX MCS isoseismal area (Figure 1). The distribution of hydrologic anomalies displays an almost linear decay away from the causative faults, with 90% of the effects within 40 km for the 1805 event [21,73]. Furthermore, small tsunami waves were reported in the Gulfs of Naples and Gaeta ([22] and references therein).

3. Data and Methods

In order to detect and characterize the detailed geometry of the buried faults along the SW border of “Il Lago” Plain, we performed a geophysical survey on the test site by means of seismic refraction and GPR methods (Figure 3).
Seismic tomography provides insights into the stratigraphy of the subsoil and the geometry of structures by analyzing the distribution of artificially generated elastic waves (e.g., [10,74]).
Ground Penetrating Radar (GPR) is an Electromagnetic (EM) geophysical methodology working at microwaves, with frequency range 10 MHz–3 GHz, commonly used to investigate shallower buried structures. Processed data allow obtaining a spatial map of the subsurface in terms of electromagnetic properties and associate the “electromagnetic anomalies” to the presence and the shape of buried targets [75]. The choice of the working frequency results as a trade-off between the necessity to investigate deeper regions (pushing to lower frequencies) and the need to have higher resolution (pushing towards higher frequencies). In particular, as long as the increase in relative dielectric permittivity improves the achievable resolution, the presence of an electrical conductivity entails losses in the soil and limits the investigation depth. The use of GPR in engineering studies, to identify structures and sources in the shallow subsoil, is well-known (e.g., [76,77]). The usefulness of GPR in geological studies is affected by the limited obtainable depth of investigation. Previous studies detected indeed only the shallower portions of faults by 2D and 3D surveys (e.g., [78,79,80,81,82,83,84,85,86,87]). In this study, we exploited a low-frequency GPR, the Loza 2N system working in the frequency band of tens of MHz, already deployed in a few other applications, [88,89,90,91,92,93], to infer the geometry of buried faults at the depth of tens of meters.
In this work, we carried out a seismic refraction tomography for detecting the presence of the main geological structures of the basin and collect information in order to better constrain the interpretation of the B-scans acquired by GPR system along profiles almost parallel to the seismic one. The acquisition of six GPR parallel profiles permitted to identify the presence of a fault zone including vertical discontinuities (Figure 3).

3.1. Seismic Refraction Data Acquisition and Processing

The seismic profile is at the SW margin of the plain and strikes SW–NE (Seis_1 in Figure 3), nearly perpendicular to the probable direction of the fault system as reported in the ITHACA dataset [40] (Figure 1). The profile was recorded in June 2020 between the foot of Mt. Patalecchia and the plain, across the Holocene lacustrine and colluvial deposits that fill the plain.
We deployed 24 horizontal geophones with a frequency of 40 Hz spaced 10 m apart over a profile of 230 m. Our seismic source consisted of a 15 kg sledgehammer that showed to produce clear first arrivals along the whole profile, thanks to the very good signal-to-noise ratio in the area (Figure 4). We performed nine hammer blows along the profile, with blows at G1, G3, G6, G9, G12, G15, G18, G21 and G24.
From data acquired along the seismic profile, we inverted the 216 first arrivals, previously handpicked on nine records (Figure 5).
The Vp model was determined by a tomographic algorithm, by using a non-linear Least Squares method implemented in the software Plotrefa. This method starts with an initial velocity model (generally a layered model generated by a time-term inversion), and iteratively traces rays through the model with the goal of minimizing the RMS error between the observed and calculated travel times (RMS error: 11.84 ms). The obtained Vp model (Figure 6) shows a high-velocity area in the SW side of the profile with a clear and significant sub-vertical velocity variation at about 20–80 m. We also depict a less abrupt sub-vertical velocity variation around 120–180 m.
Based on these preliminary seismic tomography results, we furtherly investigated the area by the GPR method by performing six high-resolution SW–NE profiles partially overlapping the seismic profile (Figure 3).

3.2. GPR Data Acquisition and Processing

In this study, the radargrams, also referred to as B-scan, were gathered by means of the Loza GPR system, which was designed especially for high-conductivity soils (wet clay, loam), at the Pushkov Institute of Terrestrial Magnetism, Ionosphere and Radio Wave Propagation (IZMIRAN) in relation with a planned space mission Mars ‘94 [93].
The GPR sensing principle is as follows: a transmitting (Tx) antenna radiates an electromagnetic signal into the probed medium, while a receiving (Rx) antenna gathers the portion of energy reflected/backscattered by the electromagnetic perturbations into the medium and occurring into a fixed observation time window. Therefore, by moving Tx and Rx antennas along a line and by collecting, at each measurement point, the backscattered field as a function of the round-trip travel time, i.e., the signal propagation time along the path Tx antenna–target–Rx antenna, a 2D image of the surveyed scenario, referred to as a radargram, is obtained. The radargram provides a representation of the subsurface features, wherein localized objects appear as hyperbola while material interfaces as constant signals, and the depth, z, of the targets is estimated by converting the round-trip travel time, t, according to the following relation:
z = c t 2 ε
wherein c = 3 10 8   m / s represents the light propagation velocity and ε is the average relative dielectric permittivity of the investigated medium [76,93].
Loza GPR is equipped with two not-shielded monostatic antennas, one Tx and one Rx, placed at the mutual distance of 6 and 10 m, respectively, for generating radar pulses at the central frequencies of 25 or 15 MHz [89]. The two antennas were moved along the profiles using a parallel (Figure 7) and/or an in-line array.
In addition, the GPR systems consists of:
(i) 
a high-power transmitter unit of 15 kV, 50 MW;
(ii) 
a receiving unit to record broadband pulses with direct signal digitization, without stroboscopic conversion and 120 dB energy dynamic;
(iii) 
two Wu–King antennas 6–15 m long without cable connection and with radio trigger placed on foils made of high-density polyethylene resistant to rubbing (Figure 7) that are resistively-loaded dipoles covered by a dielectric layer that avoids the dispersion of the transmitted signal;
(iv) 
a controller connected to the receiver unit through a coaxial shielded multipolar cable.
We collected six parallel approximately 200 m long GPR radargrams, named P1–P6, spaced about 150 m from each other. These profiles trend SW–NE, orthogonally to the main direction of the valley (see Figure 3). Table 2 reports the acquisition parameters adopted for each profile in terms of length, spatial step, and working frequency.
Figure 8 shows the raw data (B-scans) and the corresponding average trace for each scan. It can be seen how the radargrams are affected by undesired components, such as the signal due to the direct coupling between the Tx and Rx antennas and the measurement noise, which affects the useful part of the collected signal. More specifically, in the first part of time window, up to about 400 ns, each considered B-scan is affected by a strong phenomenon of direct coupling between the antennas, as also shown in the average traces in the right panels of Figure 8 and in their superposition in Figure 9.
Consequently, filtering procedures are necessary for reducing the effects of the undesired signals while improving the targets visibility. The choice of these procedures was driven by the specific surveyed scenario [75,92,94,95].
Figure 10 shows the processing chain adopted to improve the interpretability of the considered GPR data. Specifically, the data processing involves the following procedures:
  • The DeWOW procedure subtracts at each collected waveforms its mean value along the time axis.
  • The median filter, which allows removing noise from radargram and improving the results of later procedures [96].
  • The zero timing defines the actual starting time, t 0 , of the observation time window.
  • The time gating selects the portion of the observation time window where the target response occurs and allows eliminating the direct antenna coupling,   t T G , as well as the clutter signal, i.e., all the signals occurring outside the portion of the time windows of interest.
  • Background (BKG) removal helps remove or mitigate the signal contributions due to antenna coupling, air–material interface, and (undesired) horizontal reflectors.
  • Topographic correction inserts the real altitude of each acquired A-Scan and georeference the radargrams.
In this case study, the observation time window of each radargram is 2044 ns, discretized by 512 time-samples. Furthermore, on the obtained radargrams, we performed zero timing by setting t 0 = 16   ns and time gating as   t T G = 100   ns . As mentioned above and confirmed by the superposition of the average A-scans in Figure 9, the first part of the signal is affected by a strong direct coupling of antennas. For this reason, we applied the BKG removal procedure to remove this constant signal in the interval from 100 to 400 ns. Finally, we performed the two-way time–depth conversion by means of Equation (1) by assuming the relative dielectric permittivity ε = 10 . It is worth noticing that this value was chosen by exploiting the information from the seismic acquisition about the depth of high-velocity area (Figure 6).

4. Results

As mentioned above, the analysis on seismic data showed two areas with sub-vertical P-velocity variations, at 20–80 and 120–180 m. Regarding velocity values, we depicted a low velocity layer (0.3 < VP < 1 km/s) and a layer with intermediate velocities (VP ≅ 1.4 km/s). Immediately below these layers, we identified another layer with medium-high velocity values (1.6 < VP < 2.2 km/s) and high-velocity layers (VP > 2.6 km/s).
We interpret the depicted velocity variations to be caused by subvertical systems of faults, showing two horst and graben decametric structures, with NE-dipping synthetic and SW-dipping antithetic faults (Figure 11).
The GPR survey was carried out in July 2020 to confirm the information provided by the seismic survey thanks to the acquisition of data along profiles almost parallel to the seismic one. In this way, it was possible to identify the path of the fault along the overall length of the Il Lago Plain, and to achieve information about the shallower layers of the underground.
Figure 12 shows the six filtered radargram obtained by means of the data processing chain described in Section 3. The filtered data allow identifying three main areas, highlighted by three black dot-dashed rectangles (a–c in each panel of Figure 12), with strong reflections due to variations of the dielectric permittivity of the subsoil. More specifically, on the SW side of each filtered data section, we observe the reflective area (a) with a depth-to-the top of about 10 m (630 a.l.s.) and a lateral extension of about 25 m. This GPR anomaly ends with a new discontinuity that could be associated with the presence of a second change in the geological condition (black dashed rectangle b). Then, we note a third anomalous area between the distances of 100–130 m where a third geological structure is expected (black dashed rectangle c). The sequence of the three main anomalies (a–c) placed at a limited distance generally smaller than 50 m is well kept for all the radargrams acquired in the investigated foothills. Indeed, the results are similar despite the radargrams are distant up to 0.5 km, as in the cases of P1 and P6 that are the outer investigation lines.
The geophysical contrast observed in all the GPR filtered data matches quite well with the sub-vertical synthetic and antithetic structures identified by the seismic data (Profile Seis_1 in Figure 3)
We note that the anomalies detected in the NE side of the profiles are not as clear as the ones located on the SW side of the profiles. This is probably due to the strong noise affecting the GPR data and the saturation of the signal in the first part of the time window (<500 ns), likely related to the presence of clay and loamy soils. Thanks to the information provided by seismic data that show a high-velocity area on the SW side of profile Seis_1 with top at 20 m depth, the dielectric permittivity of the soils placed above the basement rocks was constrained to the value of   ε = 10 .
The correlation between geophysical results and geological data is important for a reliable interpretation in the areas with buried active faults, such as the “Il Lago” Plain. Our interpretative cross section based on seismic and geological data [49] (Figure 13) shows a sub-vertical NE-dipping normal fault, located starting from 630 m a.s.l. displacing the deposits of the plain horst and graben structure controlled by antithetical faults. We also see a SW dipping fault system that forms a horst and graben structure controlled by antithetical faults. Another horst and graben structure can be inferred on the NE side of the profile.
We interpret the layer with the lowest VP value (0.3 < VP <1 km/s) as the Late Pleistocene–Holocene slope and colluvial-lacustrine deposits of the plain. The layer with intermediate velocities (VP ≅ 1.4 km/s) is probably associable with breccias filling for about 30 m the graben. Immediately below these deposits, we identified another layer with medium-high velocity values (1.6 < VP < 2.2 km/s) that we interpret as calcarenites, calcilutites, marls, and marly limestones. The structure with the highest velocity value (VP > 2.6 km/s) corresponds most likely to more cemented calcarenites and limestones and the Mesozoic carbonate bedrock. These high-velocity areas match with strongly reflective areas of the GPR signal (Figure 12d).

5. Discussion

Surface faulting associated with the 1805 earthquake is reported in paleoseismic trench sites SE of the plain in [15,27]. However, detailed definition of the northern termination of earthquake rupture is still debated. This is due to a combination of factors: (i) the post-earthquake surveys, although carried out with appreciable descriptive effort, report coseismic surface ruptures that are tens of km apart, and with opposite dips [22]; (ii) some interpretation of the seismogenic sources in the area of Bojano and the NE side of the Matese Massif are rather simplified and are unlikely to comply with the complexity of the fault segmentation [16]; (iii) a faint constraint to the geometry of the source is supplied by the scarce and sparse instrumental seismicity that occurred over the last decades and by geodetic data [30,31,32]; and (iv) the local geomorphic and structural setting does not allow the straightforward detection of unambiguous surface breaks, as already observed in other small tectonic basins in the Southern Apennines (e.g., [8]).
In this work, we aimed at characterizing the buried structures of the area by seismic refraction tomography supported by the GPR methodology. The interpretative geological cross section based on geological and seismic data (Figure 13) shows four sub-vertical normal faults, two faults dipping towards the SW and two faults dipping towards the NE. They displace the deposits of the plain towards the north-eastern side of the basin (Figure 13). The top to the faults is at about 10 m depth (starting from 630 m a.s.l.). The inferred system forms a horst and graben structure. The GPR profiles confirmed this interpretation especially for NE-dipping normal fault, as shown, in all radargrams, where trongly reflective areas match with the structure identified by the seismic data (Figure 13). The GPR and seismic refraction data highlighted the spatial continuity of the two buried fault systems along the southwestern side of the “Il Lago Plain” for a length of about 0.5 km (Figure 3b).
The width of the SW graben likely reflects the depth at which the dip of the Mt. Patalecchia master fault changes to a lower angle (Figure 14). Indeed, the subsurface geometry of the horst and graben structure associated with the master normal fault bounding Mt. Patalecchia suggests a decreasing fault dip, from the 60° dip observed in the field to ca. 45–50° (Figure 13; Figure 14), as observed in similar gravity-graben structures for instance along capable normal faults in Nevada [97,98] or in Southern Tibet ([99] and references therein).

6. Conclusions

We carried out a study across an active normal fault at the “Il Lago” Plain (Pettoranello del Molise, Southern Italy) by newly acquired geophysical data and literature geological data. We used low frequency GPR methods combined with seismic tomography methods. As is known, the usefulness of traditional GPR techniques in geological studies is affected by the limited obtainable depth of investigation. Previous studies indeed detected only the shallowest portions of faults (e.g., [87,88]). Conversely, our study demonstrates the optimal potential of combined seismic and deep GPR surveys for investigating buried faults at depth of tens of meters (down to 60 m in this study). This can be specifically applied to young structures that, despite their probable seismogenic potential, have not yet developed mature geomorphic features or are buried under thick sequences of recent deposits. Even though the “Il Lago” Plain is a small basin within the Bojano fault system, our study adds insights into the MPFS, recognizing four buried sub-vertical antithetic and synthetic normal faults that form horst and graben structures below the plain filling. Our results suggest that the application of these geophysical techniques may allow a quick fault-detection for an accurate choice of paleoseismological trench sites. In fact, GPR and seismic data allowed inferring, from different clues and evidence, the spatial continuity of fault systems previously unknown. This result is crucial given the seismotectonic importance of the Bojano basin, for improving the knowledge of the Holocene paleoseismological history.
The geophysical evidence of Late Pleistocene to Holocene displacement beneath “Il Lago” Plain strongly suggests that recent sedimentation rates at this site are larger than the vertical component of normal faulting rate. A similar result has been already documented for instance in the San Gregorio Magno Plain, where paleoseismic evidence of Holocene surface faulting was studied with exploratory trenching across the 1980 earthquake surface ruptures [8,100]. Therefore, our investigations do not rule out that the 1805 surface faulting also affected the “Il Lago” Plain, as suggested by historical literature (Table 1). This hypothesis however needs to be verified or falsified by future trench investigations.

Author Contributions

Conceptualization, R.N., V.P., A.M.M. and S.P.; methodology, D.D., F.S., L.C., and G.L.; validation, R.N., V.P., D.D., S.P., F.S., L.C., G.L. and A.M.M.; and investigation, R.N. and D.D. All authors discussed the data, their processing and the models, and co-wrote the manuscript. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

We thank Franz Livio for the discussion on the structural setting of the Patalecchia Fault. The authors are indebted with Marco Caciagli for making available his fieldwork data on the “Il Lago” Plain, Germana Gaudiosi for her support on seismological data, Eleonora Di Marzo for earlier processing and interpretation of GPR data, Maurizio Fedi for discussion on the GPR method, and Pavel Morozov (Pushkov Institute of Terrestrial Magnetism, Ionosphere and Radio Wave Propaga-tion, Troitsk, Moscow, Russia) and Aleksandr Pitvorak for their comments on the low-frequency ground penetrating radar. The authors are grateful to three anonymous reviewers for their constructive remarks.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Seismotectonic sketch map of the study region: the study site of “Il Lago” Plain is the dark yellow ellipse; the historical earthquakes’ epicenters are from CPTI15 [24] (red squares); the Scheme 23. (orange rectangular boxes); the isoseismals (MCS intensity scale) of the 1805 earthquake are from [20] (white solid lines); the primary coseismic fractures of the 1805 earthquake are from [22] (black dashed lines); the secondary coseismic effects of the 1805 earthquake, namely liquefaction, springs increasing discharge, new springs, muddied waters, and landslides, are from [22]. Easting and northing are UTM WGS 84.
Figure 1. Seismotectonic sketch map of the study region: the study site of “Il Lago” Plain is the dark yellow ellipse; the historical earthquakes’ epicenters are from CPTI15 [24] (red squares); the Scheme 23. (orange rectangular boxes); the isoseismals (MCS intensity scale) of the 1805 earthquake are from [20] (white solid lines); the primary coseismic fractures of the 1805 earthquake are from [22] (black dashed lines); the secondary coseismic effects of the 1805 earthquake, namely liquefaction, springs increasing discharge, new springs, muddied waters, and landslides, are from [22]. Easting and northing are UTM WGS 84.
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Figure 2. Geological sketch map of the investigated area: (1) colluvial and slope debris deposits (Holocene); (2) lacustrine deposits (Late Pleistocene to Holocene); (3) cemented limestone breccias (Middle to Late Pleistocene); (4) Calcarenites, calcilutites, and marly limestone (Serravallian–Tortonian); (5) marly limestone and marl (Oligocene–Burdigalian); (6) calcarenites and cherty limestones (Senonian-Turonian); and (7) Mesozoic limestone succession (Cenomanian–Early Turonian) modified after [16,49]. The black rectangle in the map is the area shown in Figure 3; the black line is the trace of the geological cross-section of Figure 14; the blue dot is the trench investigation site is from [27]. Easting and northing are UTM WGS 84.
Figure 2. Geological sketch map of the investigated area: (1) colluvial and slope debris deposits (Holocene); (2) lacustrine deposits (Late Pleistocene to Holocene); (3) cemented limestone breccias (Middle to Late Pleistocene); (4) Calcarenites, calcilutites, and marly limestone (Serravallian–Tortonian); (5) marly limestone and marl (Oligocene–Burdigalian); (6) calcarenites and cherty limestones (Senonian-Turonian); and (7) Mesozoic limestone succession (Cenomanian–Early Turonian) modified after [16,49]. The black rectangle in the map is the area shown in Figure 3; the black line is the trace of the geological cross-section of Figure 14; the blue dot is the trench investigation site is from [27]. Easting and northing are UTM WGS 84.
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Figure 3. (a) Map of the seismic refraction (Seis_1) and GPR (from P1 to P6) profiles conducted at the “Il Lago” Plain (see the black box in Figure 2 for location); and (b) georeferenced localization of the identified structures associable to the fault system detected by GPR data. The solid light blue and yellow lines are the identified antithetic faults. The solid red and white lines are the identified synthetic faults (see Figure 13).
Figure 3. (a) Map of the seismic refraction (Seis_1) and GPR (from P1 to P6) profiles conducted at the “Il Lago” Plain (see the black box in Figure 2 for location); and (b) georeferenced localization of the identified structures associable to the fault system detected by GPR data. The solid light blue and yellow lines are the identified antithetic faults. The solid red and white lines are the identified synthetic faults (see Figure 13).
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Figure 4. Example of first P-wave arrivals of the exploratory seismic tomography survey (profile Seis_1, see Figure 3) performed in the plain.
Figure 4. Example of first P-wave arrivals of the exploratory seismic tomography survey (profile Seis_1, see Figure 3) performed in the plain.
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Figure 5. Time-distance plot of profile Seis_1. The presence of velocity lateral variations is clear between 70 and 80 m distance and around at 145–150 m distance.
Figure 5. Time-distance plot of profile Seis_1. The presence of velocity lateral variations is clear between 70 and 80 m distance and around at 145–150 m distance.
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Figure 6. Results of the seismic tomography at the “Il Lago” Plain (profile Seis_1, Figure 3), with raytracing overlaid; the red stars are the shot positions.
Figure 6. Results of the seismic tomography at the “Il Lago” Plain (profile Seis_1, Figure 3), with raytracing overlaid; the red stars are the shot positions.
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Figure 7. Parallel array of the low-frequency GPR survey at the “Il Lago” Plain; photo taken from the NE towards the SW looking Mt. Patalecchia.
Figure 7. Parallel array of the low-frequency GPR survey at the “Il Lago” Plain; photo taken from the NE towards the SW looking Mt. Patalecchia.
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Figure 8. Raw GPR radargrams with a relative average A-scan on the right side (P1–P6, see trace in Figure 3). The subplot to the right side of each profile shows the average trace of each radargram.
Figure 8. Raw GPR radargrams with a relative average A-scan on the right side (P1–P6, see trace in Figure 3). The subplot to the right side of each profile shows the average trace of each radargram.
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Figure 9. Superposition of the average A-scans.
Figure 9. Superposition of the average A-scans.
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Figure 10. The flowchart shows GPR data processing steps.
Figure 10. The flowchart shows GPR data processing steps.
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Figure 11. Results of profile Seis_1 (see Figure 3) with the detection of inferred position of faults (black dashed lines).
Figure 11. Results of profile Seis_1 (see Figure 3) with the detection of inferred position of faults (black dashed lines).
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Figure 12. (af) Filtered data of each considered GPR profile (P1–P6, see trace in Figure 3). The black dot-dashed rectangles (ac) highlight the variations of the electromagnetic response recorded along the profiles imputable to the presence of the expected geological structures.
Figure 12. (af) Filtered data of each considered GPR profile (P1–P6, see trace in Figure 3). The black dot-dashed rectangles (ac) highlight the variations of the electromagnetic response recorded along the profiles imputable to the presence of the expected geological structures.
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Figure 13. Geological interpretation along the Seis_1 profile (see location in Figure 3a): black dashed lines show the identified synthetic and antithetic normal faults and black arrows indicate the direction of displacement. Legend: (1–2) Slope and lacustrine deposits (Late Pleistocene-Holocene); (3) cemented limestone breccias (Middle–Late Pleistocene); (4) calcarenites, calcilutites, and marly limestone (Serravallian–Tortonian); (5) marly limestone and marl (Oligocene–Burdigalian); (6) calcarenites and cherty limestones (Senonian–Turonian); and (7) mesozoic limestone succession (Cenomanian–Early Turonian). Wehere merged geological units 1 and 2 of Figure 1 in one geological unit.
Figure 13. Geological interpretation along the Seis_1 profile (see location in Figure 3a): black dashed lines show the identified synthetic and antithetic normal faults and black arrows indicate the direction of displacement. Legend: (1–2) Slope and lacustrine deposits (Late Pleistocene-Holocene); (3) cemented limestone breccias (Middle–Late Pleistocene); (4) calcarenites, calcilutites, and marly limestone (Serravallian–Tortonian); (5) marly limestone and marl (Oligocene–Burdigalian); (6) calcarenites and cherty limestones (Senonian–Turonian); and (7) mesozoic limestone succession (Cenomanian–Early Turonian). Wehere merged geological units 1 and 2 of Figure 1 in one geological unit.
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Figure 14. Geological cross section along AB (whose trace and geological units are shown in Figure 2); the red box is the interpreted profile of Figure 13. Based also on data from [16,49], we interpret the shallow horst and graben structure beneath the SW border of the Plain as due to the listric geometry of the Mt. Patalecchia fault system.
Figure 14. Geological cross section along AB (whose trace and geological units are shown in Figure 2); the red box is the interpreted profile of Figure 13. Based also on data from [16,49], we interpret the shallow horst and graben structure beneath the SW border of the Plain as due to the listric geometry of the Mt. Patalecchia fault system.
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Table 1. The 26 July, 1805 earthquake-induced primary effects with contemporary descriptions of surface fault segments and ground cracks ([61,63,64,65]).
Table 1. The 26 July, 1805 earthquake-induced primary effects with contemporary descriptions of surface fault segments and ground cracks ([61,63,64,65]).
LocationTypeHistorical DescriptionRef.Note
Miranda
S. Angelo in Grotte
Surface faulting/ground crack
“A very long fracture was surveyed from Miranda, Pesche up to S. Angelo in Grotte. Especially in the upper mountain from Miranda to S. Angelo in Grotte chasms were open for about a half palm.”[61]One Neapolitan palm = 26.3 cm
Matese Mt.
Guardiaregia
Morcone
From Campobasso to Bussi
Isernia (Mt. Patalecchia)
Carpinone
Surface faulting/ground crack“In the Matese and other mountains of the county have made considerable cracks.
Very evident and deep fractures with offsets up to seven palms... you can also see horrible cracks of stones in the northern flank of Guardiareggia, and in the southern flank of Isernia. A third can be admired north of Carpinone…”
[63]Offset of about 150 cm
Pesche Carpinone Guardia regia
Matese Mt
Salcito Trivento Montagano Morcone
Surface faulting/ground crack“An opening wider than a Neapolitan palm, and more than two miles long was found throughout the back of the hill of Pesche…Carpinone also had in its surroundings two cracks, as still Guardia Regia, ... The surface of Mount Matese is all traced of considerable cracks... Equally considerable cracks were observed in the lands of Salcito, Trivento, Montagano, and Morcone...”[64]1 mile = 1845.69 m
MorconeSurface faulting/ground crack“Horrible chasms opened over a length of about one-third of a mile, some of which had the ground overthrown at a height exceeding two palms, and of which the width was over three palms and comparable the depth. These fractures now can be seen from far away, because the grass along the crevasses is desiccated as it had been on fire. In one such crevasse I observed a pear tree, that, in that moment [of the earthquake], lost all its unripe fruits, threw many branches to the ground and, of the ones left, many are now desiccated. In the same place the soil was completely disturbed, as it had excavated by innumerable moles.”[65]


1 mile = 1845.69 m
Table 2. Acquisition parameters of the GPR survey.
Table 2. Acquisition parameters of the GPR survey.
ID DataLength (m)Spatial Step (m)Frequency (MHz)Easting Start
(UTM-m)
Northing Start
(UTM-m)
Easting End
(UTM-m)
Northing End
(UTM-m)
P12032.515440,755.194,601,386.77440,890.794,601,538.72
P21852.515440,801.554,601,373.14440,951.194,601,479.89
P32062.415440,880.194,601,312.10441,033.004,601,446.72
P41992.315440,988.884,601,231.02441,142.064,601,359.67
P51601.615441,078.614,601,207.34441,202.224,601,319.15
P61983.325441,138.124,601,115.96441,290.824,601,233.27
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Nappi, R.; Paoletti, V.; D’Antonio, D.; Soldovieri, F.; Capozzoli, L.; Ludeno, G.; Porfido, S.; Michetti, A.M. Joint Interpretation of Geophysical Results and Geological Observations for Detecting Buried Active Faults: The Case of the “Il Lago” Plain (Pettoranello del Molise, Italy). Remote Sens. 2021, 13, 1555. https://doi.org/10.3390/rs13081555

AMA Style

Nappi R, Paoletti V, D’Antonio D, Soldovieri F, Capozzoli L, Ludeno G, Porfido S, Michetti AM. Joint Interpretation of Geophysical Results and Geological Observations for Detecting Buried Active Faults: The Case of the “Il Lago” Plain (Pettoranello del Molise, Italy). Remote Sensing. 2021; 13(8):1555. https://doi.org/10.3390/rs13081555

Chicago/Turabian Style

Nappi, Rosa, Valeria Paoletti, Donato D’Antonio, Francesco Soldovieri, Luigi Capozzoli, Giovanni Ludeno, Sabina Porfido, and Alessandro Maria Michetti. 2021. "Joint Interpretation of Geophysical Results and Geological Observations for Detecting Buried Active Faults: The Case of the “Il Lago” Plain (Pettoranello del Molise, Italy)" Remote Sensing 13, no. 8: 1555. https://doi.org/10.3390/rs13081555

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