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Article

An Event-Based Inventory Approach in Landslide Hazard Assessment: The Case of the Skolis Mountain, Northwest Peloponnese, Greece

1
Department of Geology, Division of General, Marine Geology and Geodynamics, University of Patras, 26500 Patras, Greece
2
Department of Geology, Division of Applied Geology and Geophysics, University of Patras, 26504 Patras, Greece
*
Author to whom correspondence should be addressed.
ISPRS Int. J. Geo-Inf. 2020, 9(7), 457; https://doi.org/10.3390/ijgi9070457
Submission received: 19 June 2020 / Revised: 15 July 2020 / Accepted: 17 July 2020 / Published: 20 July 2020

Abstract

:
Assessment of landslide hazard across mountains is imperative for public safety. Pre- and post-earthquake landslide mapping envisage that landslides show significant size changes during earthquake activity. One of the purposes of earthquake-induced landslide investigation is to determine the landslide state and geometry and draw conclusions on their mobility. This study was based on remote sensing data that covered 72 years, and focused on the west slopes of the Skolis Mountains, in the northwest Peloponnese. On 8 June 2008, during the strong Movri Mountain earthquake (Mw = 6.4), we mapped the extremely abundant landslide occurrence. Historical seismicity and remote sensing data indicate that the Skolis Mountain west slope is repeatedly affected by landslides. The impact of the earthquakes was based on the estimation of Arias intensity in the study area. We recognized that 89 landslides developed over the last 72 years. These landslides increased their width (W), called herein as inflation or their length (L), termed as enlargement. Length and width changes were used to describe their aspect ratio (L/W). Based on the aspect ratio, the 89 landslides were classified into three types: I, J, and Δ. Taluses, developed at the base of the slope and belonging to the J- and Δ-landslide types, are supplied by narrow or irregular channels. During the earthquakes, the landslide channels migrated upward and downward, outlining the mobility of the earthquake-induced landslides. Landslide mobility was defined by the reach angle. The reach angle is the arctangent of the landslide’s height to length ratio. Furthermore, we analyzed the present slope stability across the Skolis Mountain by using the landslide density (LD), landslide area percentage (LAP), and landslide frequency (LF). All these parameters were used to evaluate the spatial and temporal landslide distribution and evolution with the earthquake activity. These results can be considered as a powerful tool for earthquake-induced landslide disaster mitigation

1. Introduction

A common approach for studying slope failure by an earthquake or cumulative earthquakes is the inventory of the induced landslides. Landslide inventory, according to Cruden [1] and Fell et al. [2] is the record of the location, classification, volume, activity, and date of occurrence, where known, of individual landslides in an area as inventory maps. Although inventory maps have received particular attention for landslide susceptibility, landslide maps cover less than 1% of the slopes in the landmasses, and systematic information on the type, abundance, and distribution of landslides is lacking. [3]. There are many criteria for long-term inventory maps depending on the purpose or the extent or the available remote sensing data (i.e., aerial photographs or satellite images) that contribute to its temporal completeness [4,5]. Furthermore, in the case of earthquake-induced landslides, the completeness of the records of local seismicity are also very important. Thus, it is necessary to have a consecutive time series of remote sensing and earthquake data to determine the reactivation and appearance of old and new landslides, respectively. According to Xu [6], landslide inventories based on remote sensing data can avoid missing a large number of small scale landslides and can obtain detailed and comprehensive earthquake-triggered landslide inventories.
Beginning in 1984, syntheses of worldwide and national data on earthquake-induced landslides have defined their general characteristics and relations between their occurrence and various geologic and seismic parameters [7]. For these reasons, the need to create databases that include parameters and landslide characteristics has become more intense. The latter led to the production of landslide inventories, which were associated with an isolated severe seismic event or the cumulative effects of events as trigger factors [8]. While most early workers have highlighted the importance of the inventories [9,10,11,12,13], the first well-known digital inventory map for earthquake-triggered landslides was compiled by Harp and Jibson [14]. Since then, many landslide inventories have been prepared in relation with moderate or strong earthquakes [3,6,7,14,15,16,17,18,19,20,21].
Three main techniques are used to correlate the landslide hazard to earthquakes. Inventory of landslide evolution over time is based on the geometrical characteristics of the earthquake-induced landslides [3,8,19,22,23,24,25], historical seismicity, and consideration of the Arias empirical intensity [26,27,28]. Since these three techniques involve a large amount of data, the mapping and analysis were implemented in a geographic information system (GIS). Furthermore for the qualitative and quantitative analysis of landslide distribution across a bluff, the estimation of the landslide density (LD), the landslide area percentage (LAP), and the landslide frequency (LF) over time is of particular importance. The LD expresses the number of landslides per square kilometer, the LAP is defined as the percentage of the area affected by landslides, and the LF is calculated by dividing the density of landslides by the analyzed time interval.
The work in this paper builds on the past work of Koukouvelas et al. [29], which presents abundant and isolated landslides induced during the 2008 Movri Mountain earthquake on the Skolis Mountain west slope. In [29], the authors examined the effect of different factors such as the morphology of the Skolis Mountain, the climate, the pre-existing faults, and the seismicity as triggering factors for landslides. The result was that slope angle and earthquakes are directly controlling the induced slope failures. Other slope factors like gradient, direction, length, and shape are slightly changing along the mountain, while factors like drainage density, rock types, structural data, etc. are not crucially significant factors.
In this work, we analyzed the landslides detected from aerial photographs or satellite images in a 72 year period as well as tried to highlight the role of seismicity on their temporal evolution. Our datasets comprise orthorectified aerial photographs and satellite images covering the period 1945–2017. In addition, we considered the Arias empirical relationships of all earthquake events with magnitudes above 4.0 in the NW Peloponnese to refine the events affecting the Skolis Mountain. A regression analysis was performed by correlating the number of landslides and their area, in order to consider if these two parameters have evolved over time. To improve the reliability of our landslide evolution model, we applied statistical analysis of the landslide evolution and quantitative analysis of the geometric characteristics of the landslides. This inventory, across a 10-km-long slope, is presented for the first time in Greece. Finally, we applied the length–width (aspect ratio) and height–length ratio (reach angle) of landslides when trying to introduce the future mobility of landslides in this study area.

2. Geological Setting

On 8 June 2008, a strong earthquake of Mw = 6.4 struck northwest Peloponnese, called herein as the Movri Mtn earthquake [30,31] (Figure 1). The epicentral area of this earthquake incorporated a significant part of the NW Peloponnese while across the Skolis Mtn, extensive landslides and rockfalls were mapped [29,32]. Santomerion village, located on the west bluff of the Skolis Mtn, suffered by far the most damage due to landslides, among five others around the Skolis Mtn. These damages were due to the proximity of the village to steep slopes of the mountain (Figure 1). As steep slopes are commonly developed in limestone mountains in Greece [33], many Greek villages are prone to analogous risk during strong earthquakes. The earthquakes play a significant role in most of the slope failures (see also [9] for worldwide data, and [34,35] for Greek data). However, the exact role of earthquakes on the landslides in Greece is poorly understood. According to Keefer [7,9], moderate to strong earthquakes have long been recognized as a triggering factor of landslides. Earthquake-induced landslides can be either located on active faults or in the epicentral area [9,35,36]. Notably, an earthquake magnitude threshold for triggering landslides is 4.0 on susceptible slopes; while earthquakes with magnitudes greater than 6.0 can generate widespread landslides (see as an example Jibson and Keefer [37]). In mainland Greece, the recurrence interval of earthquakes of magnitude larger than 4.0 is short, and thus a significant part of the country is prone to earthquake-induced landslides. Consequently, the inventory studies of landslide prone-areas are crucial for civil protection purposes.
NW Peloponnese and its surroundings are located within the most tectonic active and seismic region of Greece [38,39]. The Skolis Mtn developed as a fault-related-fold located at the tectonic boundary between the Ionian and Tripolitsa units [29]. The Skolis Mtn is an anticline almost 10-km-long, 1.5-km-wide with N–S orientation characterized by a west-dipping short limb, and an east-dipping long limb (Figure 1). The mountain’s morphology resembles its structure with its west bluff being short and steep while its east one is longer, dipping shallowly (Figure 1).

3. Materials and Methods

In this work, we investigate and verify the spatial and temporal distribution of landslides across the Skolis Mtn between 1945 and 2017 (Figure 1, Figure 2 and Figure 3). Aerial photographs of 1945 were selected as the base since they corresponded to the oldest available dataset in Greece. Satellite images from Google Earth during 2017 were the newest available data after a period of high seismicity in the area. For the entire inventory period, we used all the available aerial photographs and satellite data in this area, as described in Table 1. It is noteworthy that the acquisition of the remote sensing data used in this study is irregular in the analyzed time interval. In particular, 1945–2007 remote sensing data acquisition intervals range between 9–15 years; for the period 2007–2009, the data correspond to one image per year and for the period 2010–2017, correspond to two available datasets during 2015 and 2017.
Overall, for the landslide inventory, we used ten (10) sets of remote sensing data. Geometric distortions, caused by viewing geometry and platform instability, are common in remotely sensed imagery. All aerial photographs were rthorectified to correct all possible geometric distortions following the methodology as described in Litoseliti et al. [40] and Koukouvelas et al. [29]. The digital orthomosaic and the digital surface model (DSM) from the National Greek Cadaster and Mapping Agency used as reference base maps for the selection of 84 ground control points for the orthorectification of all the other datasets.
The base map orthomosaic has a spatial resolution of 0.5 m, while the respective DSM has a spatial resolution of 5 m and a nominal vertical accuracy better than 2 m. We also used Google Earth (GE) scenes as an additional tool for the spatial distribution of landslides. Note that although the horizontal positional accuracy of the GE data has questioned (i.e., [41,42]), the data of the GE scenes are used in many studies to produce landslide maps or landslide archives (e.g., [3,43,44,45]). Additionally, Hu et al. [46] proved that GE imagery provides similar classification results compared to the original Quickbird satellite images. In a recent study [47], it was proven that vectors derived from the GE images presented negligible differences in length derived from the orthorectified images. Characteristic examples are presented in Figure 2. The onscreen mapping of each landslide site on the remote sensing data was finally performed at the 1/1000 scale. First, the perimeter of each landslide was digitized and then isolated trees or tree stands were also digitized. Specific attention was paid during the landslide limits of digitization to exclude the canopy shadow into the tree stands and the bedrock into each slide area. Finally, the areas of the trees or tree stands were subtracted from the landslide polygon area. A detailed discussion on the whole methodology is described in Koukouvelas et al. [29].
In specific areas, the mapping completed by data given from the extra fieldwork. The fieldwork was focusing on mapping the outline of the borders of the landslide sites, particularly in areas of dense vegetation. The data stored in a GIS environment (ArcGIS 10.1). Considering the mentioned methods, Table 2 and Table 3 summarize the landslide data in the studied area. In specific cases, we also used our laboratory archive photos and photos collected during the fieldwork after the 2008 earthquakes.
The spatial distributions of the landslides are presented as LD and LAP within the different orthomosaics. The qualitative analysis includes the geometrical characteristics of the landslide sites, and quantitative analysis focuses on their aspect ratio.
The landslides in the Skolis Mtn are classified as fragmental rock falls, a term describing the movement of individual fragments that move as independent rigid bodies interacting with the substrate during episodical impacts [48]. These landslides are transitionally classified between rock falls and rock avalanching following Hungr et al. [49] and include individual fragments that descend slopes, bounce, and roll, while at a mean slope of <30° finally stop [50]. The continued occurrence of rock fragments produces a deposition zone of rock fall taluses or clusters of boulders downslope (Figure 2 and Figure 4a). However, as rock falls, rock slides, and rock avalanches are sometimes difficult to distinguish one from the other, therefore, for simplicity, we will use the general term landslide in this study. These landslides are elongated showing (a) narrow rectilinear or (b) curvilinear paths, thus classified for brevity as I- or J-, respectively. The third type of landslides is classified as Δ-shaped includes the elongate path and fan-shaped deposition area (Figure 4a). Δ-shaped landslides are in common characterized by more than one landslide paths. In our case, these three types of landslides usually involve volumes smaller than 105 m3.
Rainfall data in the Skolis Mtn area for half a century indicates that the period from April to September is almost dry with the high raining season concentrated from October to March. Testimonies of local people indicate strong consensus that landslide reactivation is a rather uncommon phenomenon, except at the beginning of the humid period (i.e., each October). The monthly precipitation varies from 8–60 mm in the dry period to 78–150 mm in October–March. Since the area is not prone to heavy rainfalls and floods, rainfall as a triggering factor appears to be less significant in comparison with the earthquakes. This suggestion is following the landslide mapping (Figure 2 and Figure 3) where the post-2008 landslides are remaining dormant or stable for long after the Movri Mtn earthquake. In some cases, earthquakes act as predisposing factors while rainfall is considered the main trigger of landslides [51]. However, the Skolis case appears to be the opposite, where earthquakes are the main triggering factor [29] (see also Figure 4d and Figure 5). In particular, in Figure 4d, it can be observed that the number of landslides increased abruptly just after the 2008 earthquakes.

4. Landslide Inventory

In total, across the Skolis Mtn over the 1945–2017 time intervals, we mapped 89 landslides affecting an area of 3.9 km2 (Figure 1). The affected area covers elevations from 350 m to 970 m (Figure 4b) with their length and width appearing in Figure 4c. These parameters, together with the height of the landslides, are primary data that consist of 267 measurements; 89 values for each parameter, as derived in 2017 orthophotomaps. Moreover, the diagram in Figure 4b delineates the slope height as an important physical parameter that affects landslide occurrence. Additionally, 65% of the landslides were concentrated in the elevation range of 600–800 m. To determine the rate of qualitative and quantitative landslide evolution, we composed ten inventory maps showing the interpretative landslide distribution during isolated earthquake events or their cumulative effects due to many earthquakes that left identifiable traces (Figure 5 and Figure 6). For brevity, we present in Figure 5 ten maps analytically showing the evolution of 21 landslides for a 1500 m long part of the Skolis Mtn. This part of the mountain is the most significant since this is close to the Santomerion village.
Apart from the qualitative and quantitative landslide evolution, Figure 6 indicates that even without seismic events, there is a slight increase in landslide area. In particular, high seismicity periods with enormous landslide increase are followed by a small landslide increase. A detailed example of the latter is depicted in Figure 6a,b in landslide number 16. The estimated values of length and width relative to acquisition date were 45 and 44 m from 1945–1987, 85 and 71 m in 1996, 106 and 94 m in 2007, while they were 151 and 113 m in 2008, and 154 and 117 m from 2009–2017, respectively. Results showed an error of less than 2%.

5. Use of Randomly Acquired Aerial and Satellite Photographs for Landslide Inventory

A common problem with past landslide inventories is that the aerial photographs were acquired at irregular time intervals commonly not for landslide inventory. In our case, from 1945 to 2007, the aerial photographs were acquired at time intervals ranging from 9 to 15 years in a random way (Table 1 and Figure 4d). Thus, our inventory periods are imposed by the acquired remote sensed data and so the proposed inventory does not cover isolated events, but rather a cluster of events. As aerial photography data are non-repeatable, it is a real challenge to try to study landslides with biased data. Furthermore, this challenge is more complicated when the aerial photographs are intercalated in a time series with earthquakes that trigger landslides. As an example in the case of the earthquake events from 1989–1993, the closest aerial photographs were acquired during 1996, and thus our analysis is not detailed enough. Thus, for the cluster of the 1989–1993 earthquakes, we used an orthophoto map during 1996. In the same period between 1993 and 1996, there was no earthquake activity, so we considered that the orthophoto map of 1996 was interpretative of the slope failures from 1989–1993.
However, there is a question posed, of what happens when earthquakes and seismic quiescence are repeated every second year like in the period from 2010–2017? Trying to address this question, there are two orthophoto maps during 2008 and 2009. These maps show that even in these two years, the seismic activity was intensive and the landslide evolution was rather limited. This suggestion indicates that either our method was not detailed enough to monitor the landslide evolution annually, or the recorded landslides have slowly been evolved. Nevertheless, if this result is correct, then it is highly possible to consider that the orthophoto map of 1996 is more or less interpretative of slope failures during the period from 1989–1993, and similarly, the orthophoto map of 2007 showed the role of the seismicity during the 2003 seismic period on the landslides across the Skolis Mtn. In particular, our landslide inventory included two well defined periods of seismic quiescence from 1945–1987 and 1994–2002. The rest of the 72 years was discriminated in seismic periods. The 2010–2017 landslide inventory period was characterized by an overall progressive decrease in seismicity in a stepwise manner. Therefore, we considered this alternation of earthquakes and seismic quiescence as a third motif affecting the evolution of the Skolis Mtn slope failures. This motif includes a seismicity decrease in a stepwise manner with an earthquake every second year or so, that lasts for eight years. At present, the seismicity in the area is absent. Summarizing, within the 72 years, we recognized two well defined periods of seismic quiescence in the order of eight and 42 years. Each seismic quiescence, followed by three short periods of seismicity, outlasting 5, 4, and 2 years. During the last seven-year-long period, the seismicity occurred almost every second year or so (Figure 5 and Figure 6 and Table 1). Based on these data, the herein presented inventory can be considered as an event(s)-based one.

5.1. Seismic Quiescence Period 1945–1987

Over the first 42-years of the landslide inventory period, only an earthquake was recognized in reasonable distance and magnitude from Skolis Mtn during 1960 (Figure 5 and Figure 8). Consequently, the inventory maps of the landslides showed remarkable stability in their number and dimensions. This 42 year period shows that the majority of the landslides (86%) were inactive, while 14% showed minor changes. The LAP over this period displayed values of 0.86% during 1945 and 0.98% during 1987. The LD has increased from 10.77 to 12.56 landslides/km2, over these 42 years (Table 2).

5.2. Seismic Period 1988–1993

Five earthquake events above 4.6 inflicted the study area from 1988–1993 with three of the earthquakes above 5.2 (Figure 8 and Table 1). These events triggered 23 new landslides appeared in the 1996 orthomosaic (Table 2 and Figure 5). In this time period, the LAP increased by 150% and the occupied area increased from 38.096 to 95.699 m2 (Table 2 and Table 3; Figure 4d and Figure 5). Therefore, in the 1987–1993 time-interval, landslide triggering appears to have occurred under a cluster of seismic events within epicentral distances in the order of 5–10 km. In this time interval, LD increased proportionally with the increase in LAP from 12.56 to 18.46 landslides/km2 and from 0.98 to 2.45%, respectively (Table 2).

5.3. Seismic Quiescence 1994–2002

The chronological gap in our data was due to the lack of available aerial photographs and coincided with the observed absence of seismicity (Figure 8c). Recognizing this limitation, the analysis of this period has processed concerning possible biases. Since the next seismic sequence appeared in 2003, we cannot assert a change in landslide area during 1994–2002.

5.4. Seismic Period 2003–2007

As discussed earlier, the slope failures of the multiple events of 2003 were mapped in the orthophoto map of 2007 (Figure 8c). More specifically, the 2007 orthomosaic landslide activity was recognized as moderate when compared to those of the previous period. Particularly, the affected area changed from 95.699 to 118.020m2, showing an increase of 23% (Table 2 and Table 3).

5.5. Seismic Period 2007–2009

The analysis of this period is represented by three orthomosaics composed of several GE scenes in a high seismicity period (Table 1 and Figure 5). Furthermore, the use of 2007 and 2008 aerial photographs, and the orthophoto maps of this year was completed by field data. Regarding this period, two conclusions have been made: (i) after the Movri Mtn earthquake, a significant increase of the number of landslides is recognized, accounting for nearly one-quarter of new landslides developed in the Skolis Mtn; and (ii) a dramatic increase in the affected area from 118.020 to 242.198 m2. Moreover, the LAP and the LD showed an increase of 109% and 19%, respectively (see Table 2). We also concluded that the Mw = 6.4 event was, beyond any doubt, a severe series of earthquakes that triggered 14 new landslides in the Skolis Mtn (Table 2).

5.6. Seismic Period 2010–2017

Observations of the 2010–2017 period show that a minor increase in landslide distribution in the order of 5% indicate the positive correlation between seismicity and landslides (Figure 5 and Figure 8b and Table 2). This was possibly due to moderate earthquakes (Figure 8b). The LAP increased by 9%, while the LD remained stable.

6. Results

6.1. Geometric Parameters of Skolis Landslides—Aspect Ratio

The geometric analysis of the measured landslides is based on their length (L) equal to the maximum distance from the toe to the crown and the width (W) as the maximum amplitude perpendicular to their length (L). Another parameter that characterizes landslides is their height (H), defined as the elevation difference between the landslide crown and the toe [52]. We used GIS software to obtain the L, W, and H parameters. From this perspective, we calculated the aspect ratio and the reach angle of the landslides. The aspect ratio is defined as the landslide length to width (L/W). The reach angle is the arctangent value of the height–length ratio (H/L). To estimate the aspect ratio (L/W), we created a minimum bounding rectangle that enclosed the corresponding values of length and width for each landslide site along the direction of movement [52,53] (Figure 4a).
Two significant results are outlined by aspect ratio analysis. First, the aspect ratio is changing over time. Second, each type of landslide has quite a discrete aspect ratio (Figure 4c). Overall, the aspect ratios vary in the range of 0.4 ≤ (L/W) ≤ 5.2, with a mean value of 1.8. In particular, the 89 landslides based on the aspect ratio are classified as I-, J-, or Δ-type, indicating the following ratios, I-type landslide 2.2 ≤ (L/W) ≤ 5.2, and J-type landslides 1.2 ≤ (L/W) < 2.2 (see Table in Figure 7). I- and J-type landslides start at high elevation steep slopes of the mountain, also indicating the longer runout distances. The Δ-type landslide shows the ratio (L/W) < 1.2 at moderately inclined slopes. I- and J-type landslides correspond to 64% (N = 57) and are the dominant type identified near the Santomerion village, the most important area in terms of hazard (Figure 8a).
At the Santomerion area, the aspect ratio increased over time from 1996–2017, primarily in the I- and J-type landslides (Figure 6 and Figure 7b). The I-type landslide shows primarily a length increase in the order of 13–30%. In contrast, the J-type landslides, over the same time period, are bimodal, characterized either by predominant length or width increase (Figure 7b). Particularly important is that the J-type landslide shows significant mobility and increase in their length or width in the order of 100–500% (Figure 7b).

6.2. Estimation of Arias Intensity for Historical Events

The Arias intensity is a measure of the total seismic energy that is ground absorbed and is based on instrumental records. A large number of empirical attenuation relationships have been tested and evaluated in recent years with the one developed by Danciu and Tselentis [54] to incorporate data primarily from the Greek territory. Events that appeared in Figure 8 are those suggested as capable of causing slope failures in the Skolis Mtn following the Arias intensity (Ia) according to the Danciu and Tselentis [54] equation:
log I a = a + b M c log ( R 2 + h 2 ) + e S + f F + ε ,
where M is the magnitude; R is the epicentral distance from the event to the location; h is the “fictitious” focal depth; and the variables S and F refer to the site classification and fault mechanism, respectively. The soil condition coefficients, e and f, are considered independent of magnitude, distance, and level of ground shaking. The model error is given by ε and is normally distributed with zero mean.
In order to evaluate the range of the earthquake magnitudes that possibly trigger landslides in the Skolis Mtn, we estimated the critical epicentral distance according to Papadopoulos and Plessa [55], which is defined by the equation:
log ( R e ) = 2.98 + 0.75 M s     for   M s 5.3 ,
where the equation uses seismic magnitudes (M) and their distance of the Skolis Mtn (R).
The calculated values of the Ia are outlined in the diagram of Figure 8 for the events in the NW Peloponnese.
Out of the 86 recorded seismic events during the 72 year inventory period, 26 events with magnitudes above 4.2 indicate that Ia possibly correlated with the Skolis Mtn landslides (Figure 8). These earthquakes are located mainly to the north and west of the mountain. In Figure 4d and Figure 8, seismicity pre-dates the increase in the number of landslides during the three periods. In the same period, the climatic data and rock tectonics were stable; the appearance and the aspect ratio development of the landslides are related to the earthquakes in the table of Figure 8. In detail, this progressive evolution of landslide sites is plotted in Figure 4d and Figure 5.

6.3. Statistical Analysis of Landslide Area Evolution

The affected area is about 293.000 m2, occupying 7.5% of the total area (Table 3). The statistical analysis of landslide spatial and temporal distribution for the last interval indicates a minimum, mean, and maximum value of affected area of 148, 3329, and 23,828 m2, respectively (Table 3). Furthermore, the analysis of data on the extent of area affected by long-term seismicity in the Skolis Mtn indicates that the 1989, 1992, and 1993 earthquake activity resulted in a 49% increase of the maximum landslide area, while the minimum area remained stable (Table 3). In contrast, the 2008 earthquake activity showed that 118% of the minimum and 112% of the maximum landslide area has been increased (Table 3). Although the increase of the seismically induced larger landslides is mapped (Figure 5), the stability denotes that the 1989, 1992, and 1993 earthquake activity have not affected the smaller landslides, in contrast to the 2008 earthquake (Figure 5 and Figure 8 and Table 3). Therefore, the size of smaller landslides depends primarily on the seismic magnitude for Mw ≥ 5.6, and secondarily, on the maximum distance from the epicenter. Moreover, statistics of landslide distribution (Figure 4d and Figure 9) including correlation of two landslide proxies are described below (Figure 9b,c and Figure 10).
The charts in Figure 9c represent a plot of the cumulative number of landslide area relationship for earthquake-induced landslides from 1945 to 2017 in the Skolis Mtn. The up to now knowledge of the effects of independent variables on dependent variables can help us understand the evolution of the spatial distribution of landslides during a seismic event. Therefore, we created a scatter chart showing the relationship between x and y (independent and dependent variable) for the original data using a power regression model (Figure 9c). This model is based on the following equation:
y = α x β ,
Thus, our dataset yields a power curve with the relationship:
y = 0.0057 x 0.9136 ,
with R2 = 0.85. Since the exponent is so close to one, the curve is almost a straight line.
In agreement with the aforementioned results, there is a significant positive relationship between the number of landslides and the affected area, R = 0.92 (R2 = 0.85) in this regression analysis. The P-value was 0.000148, less than 0.001, which indicates that the correlation between cumulative number of landslides and affected area is statistically highly significant. It constitutes a continuous process of causal reasoning and hence the curve in the regression analysis is almost a straight line (Figure 9c). Likewise, Figure 9b shows an accumulative curve of landslide occurrences. The slope b = 0.9303 was positive, indicating that as the percentage of landslide number increases, the percentage of landslide area also increases. In this regression analysis, the P-value was 0.00000052 (or 5.2 × 10−7), less than 0.001, which indicates that the correlation coefficient was statistically highly significant. The correlation of determination R2 = 0.96 can be considered as excellent, suggesting that the model is valid.
The statistical analysis of landslide occurrences is described in Table 2 by using three indices: LD, LAP, and LF. Most landslide sites in the Skolis Mtn exhibit a critical behavior, which is reflected by a continuous increase in their number and size over the 72 year period of record, indicating a LAP of 7.51%, a LD of 22.82 landslides per square kilometer, and a long-term average LF of 7.3 landslides∙km−2∙yr−1. Calculation of the latter three parameters is advantageous in the Skolis case and in similar cases of seismically active areas.
The diagram in the following figure (Figure 10) depicts correlations between landslide occurrences and the chronological dates of landslides and affected area (Figure 10). Particularly, Figure 10 shows the percentage of the area occupied by a number of landslides relative to acquisition date. This plot shows a stability from 1945 to 1987, from 1996 to 2007 (see Section 5), and from 2010 to 2017, which corresponds to the period of seismic quiescence. Contrariwise, from the 1987 to 1996 and 2007 to 2009 seismic periods, we can notice that the LAP value (dots) demonstrates a more significant increase than the LD value (bars). The latter approves the considerable increase of the landslide mass, in terms of inflation and enlargement, which affects the whole landslide body. Therefore, the reactivated landslides of the abovementioned seismic periods, not only occurred within the pre-existing landslide masses, but have also been fully mobilized by significantly increasing their size (Figure 5 and Figure 6 and Table 3). Thus, apart from the appearance of new landslides, there was an even higher increase of landslide area.
More specifically, Figure 10 and the curves in Figure 9b,c indicate that apart from the appearance of new landslides, there was an even higher increase of landslide area. The reasons for this fact are: (i) the reactivated landslides occurred within pre-existing landslide masses, increasing their size; (ii) the larger landslides occurred at higher elevations, where most instability phenomena take place; and (iii) the majority of the earthquake magnitudes in the Skolis Mtn territory affected the larger landslides more than the smaller ones, as described earlier in this section (Table 3).

6.4. Qualitative Analysis

Post-Earthquake Landslide Morphological Evolution

The post-earthquake results indicate that the deposition area corresponds to the accumulation zone forming new taluses. This process is mainly characterized by an increase in (i) width (inflation) that strongly affects Δ-shaped landslides, and (ii) the main landslide body [52] shows an increase in length (enlargement) that affects primarily the I- and J-shaped landslides. Apart from the inflation that occurred in the deposition area of all landslides, an enlargement in most of the landslides took place. It is worth mentioning that the enlargement is considered as the factor that contributes more than the inflation to the local vulnerability due to the proximity of the Santomerion and Portes villages to I- and J-landslide types (Figure 5 and Figure 6). The enlargement is the main process increasing the risk in the Skolis communities with the increase of the I-, J-, and Δ-shaped landslides during the earthquake.
The rock fall dimension data were evaluated using ArcGIS. Hence, the estimated minimum and maximum lengths of the I-, J-, and Δ-shaped landslides were 40, 18, and 10 m and 395, 342, and 203 m, respectively.

7. Discussion

Landslide inventory maps are the key component of a landslide hazard or risk assessment, particularly when they are comprised of seismic catalogs, continuous imagery, acquisition dates, and accurate estimates of affected area (volume, area).
A multi-temporal landslide inventory of earthquake induced landslides led to the understanding of the earthquake imposed hazards and to the development of models and methods for hazard mapping and evaluation [7,18,56]. The information we provide with this method can be used as an advantageous tool in hazard or risk assessment. In general, the examination of landslide behavior is a reliable solution to estimate the future evolution and to predict its mitigation provided us with knowledge to prevent forthcoming disasters. Since we meet the landslide inventory and mapping criteria, described by Harp et al. [17], the inventory will be of sufficient accuracy and completeness to accommodate seismic landslide hazard analysis. In order to make a reliable map that predicts the landslide hazard and risk in a certain area, it is crucial to have insights in the spatial and temporal frequency of landslides, and therefore each landslide hazard or risk study should start by making a landslide inventory that is as complete as possible in both space and time [5,57,58,59].

7.1. Reach Angle

The local tectonic grain in the study area, which is mainly represented by an anticline and Skolis Thrust Fault, has formed and shaped the characteristic natural steep slopes of Skolis Mtn [29]. In slopes covered with scree deposits, debris failures are expected to occur on slope angles over 30° [60]. Dai and Lee [61] carried out a statistical analysis of landslide height–length (H/L) ratios of 2135 landslides in Lantau Island, Hong Kong, providing the relationship of landslide H and L as H = 0.524L + 1.257, R2 = 0.87, and the average reach angle of 27.6° (arc tangent 0.524). In addition, Qi et al. [62] performed an analysis of landslide height–length ratios of 66 long runout rock avalanches from the 2008 Wenchuan earthquake and obtained a relationship that is H = 0.2638L + 212.4, with R2 = 0.6716 and average reach angle of 14.7°. Similarly, Xu et al. [63] obtained the relationship H = 0.595L, with R2 = 0.6972 and average reach angle of 30.7°, based on 453 landslides from the 2010 Haiti earthquake. Thus, we used the height (H) and length (L) of 89 landslides from the 2008 Movri earthquake to yield the regression relationship: H = 0.6645L + 3.7235, with a coefficient of determination of R2 = 0.9209 (Figure 11). This means that the average reach angle is about 33.6°, which is close to the arc tangent value of the friction coefficient of most natural rock types (≈30°), according to Corominas [64]. Figure 11 shows the strong positive correlation (0.92) between the horizontal length (L) and change in elevation/height (H) using a scatterplot. Figure 11 shows the fitting lines of the H/L ratios using data from previous studies. The comparison between the aforementioned studies and the current one indicates that the reach angles were in the range of 27.6° to 33.6°. Nevertheless, we noticed the small reach angle in the results of Qi et al. [62], which can be explained by the fact that the larger the landslide, the smaller the angle of reach obtained [60,64], as the rapid-moving avalanches travel a long distance.

7.2. Aspect Ratio

Seismicity is undoubtedly a significant landslide triggering factor like the case in Santa Susana during the Mw = 6.7 Northridge earthquake. According to Parise and Jibson [65], single landslide areas ranged from 23 m2 to more than 25.000 m2 and averaged 1.520 m2. Similarly, in the Skolis Mtn, the landslide areas ranged from 50 m2 to 23.830 m2 and averaged 3.328 m2. Furthermore, the estimated aspect ratios had a mean ratio of 2.6, while in the case of Skolis Mtn, the mean aspect ratio was 1.8. While the elevations of the Skolis and Santa Susana Mountains range from 350 to 970 m and 270 to 950 m, respectively, there was a difference between their average aspect ratios. We assumed that the difference was due to the fact that the Skolis Mtn area is represented by landslides while Northridge mainly by single landslides showing long runout distances. This factor determined the shape (extent of elongation) and the enlargement of landslides.
As the Skolis Mtn is located in an area prone to strong earthquakes, the need to define landslide hazard zones is imperative. Monitoring of landslide evolution provides insights into: (i) the development of unstable rock slopes in relation to their proximity to residential areas, showing the landslide potential to exceed the moderate-risk zone and reach the high-risk zone; and (ii) the maximum runout distance at 27°. The latter indicates that some villages in the area located between 27° and 33.6°, within the zone of high to moderate-risk (Figure 12).

7.3. Recurrence Period and Rate of Length

After a detailed estimation of the length of each landslide site, we selected fourteen of them due to their proximity to Santomerion village (Figure 13). The rate of length was defined as RL = ΔL/Δt, where ΔL is the difference between the length of the last and the first observation and Δt is the time interval and is expressed in meters per year (m yr−1). Thus, fourteen rates of length were calculated for the corresponding landslide sites in the Santomerion area, between the oldest (acquisition) and the most recent date (1945–2017). The RL of the particular landslide sites ranged from 1.1 to 4.8 m yr−1 with a mean of 2.3 m yr−1 (Figure 13).
The evaluation of our multi-temporal inventory indicates a periodic recurrence of earthquake-induced landslides after critical events, thus suggesting a length-predictable earthquake recurrence model. According to this model, it is considered that there is no significant increase in periods of seismic quiescence. The increase takes place when an earthquake of critical magnitude occurs; each seismic period will end when the next critical event occurs at a random time tx (yr).
Eventually, in order to enhance and improve our previous data, we created a landslide inventory that also encompassed quantitative and qualitative data. The authors focused on the quantitative and qualitative analysis in conjunction with the multi-temporal, spatial, and statistical analysis aimed at presenting the results to potential users. Further developments are the use of the Skolis model: (i) in correlation with other landslide prone anticlines with similar characteristics; (ii) to determine the probability of potential landslide occurrence in mountainous areas; and (iii) to construct probabilistic prediction models.

7.4. Hazard Map

This analysis can be summarized in the compilation of a large-scale landslide hazard map (Figure 14). This map involves the probability of landslide enlargement based on (a) the shape of landslide at different time intervals, and (b) calculation of the assessed landslide annual evolution rate.
According to their shape (I, J, and Δ), the landslides are classified in three categories, rated from 1 to 3. The landslides that form a Δ-shape are characterized as less dangerous and rated with value 1, while the I-shaped landslides are the most dangerous, rated with value 3. The enlargement rate of these landslides range between 0.5 and 4.8 m/yr. As quantitative hazard and risk acceptance criteria are usually expressed in annual terms, the annual evolution rate of each landslide measured in m yr−1 is used in order to classify the landslide hazard. The evolution rate is classified in four categories from 1 to 4. The enumeration of the two factors (landslide shape and annual evolution rate) is presented in Table 4. Spatial interpolation algorithm has been used in order to produce the landslide hazard map (Figure 14).

8. Conclusions

In this work, landslide events that have occurred in the Skolis Mtn were compiled as an event-based landslide inventory comparing the pre-event and post-event landslide inventory. The comparison between multi-temporal data displays corresponding to different periods makes it possible to determine the enlargement and inflation of landslide sites. Geomorphological and seismic analysis with data processing in a GIS environment allowed us to define the spatial and temporal distribution and the activity of landslides on the west slopes of the Skolis Mtn. Our results are summarized as follows:
  • The existence of former landslides constitutes the determinant factor. The reactivated landslides not only occurred within pre-existing landslide masses, but they have also been fully mobilized by significantly increasing their size up to three times.
  • Although the proportional increase of the larger landslides resulting from the Arias intensities is expected, the increase of the smaller landslides is subject to certain limitations such as seismic magnitude, Mw ≥ 5.6 and distance from the epicenter, R = 11 km. The outcome of this process is a landslide inventory map through the GIS environment showing the size and distribution of landslides triggered by a Mw = 6.4 earthquake (Figure 5 and Figure 14).
  • Increased percentages of LAP and LD negatively affect the slope stability, especially in the last two decades (Table 2). The coincidence of the high LAP and LD with moderate to strong earthquakes also suggests potential slope failure in an area prone to landslide phenomena.
  • The calculation of the rate of length is quite crucial. High RL values along with seismic activity can be used for the evaluation of landslide hazard assessment of inhabited or unstable areas.
  • The proposed model of the inventory analysis is coherent with the interpretation of the temporal and spatial distribution showing high periods of stability and short periods of rapid length evolution during short periods of seismicity. Our method is interesting both for (i) the landslide mapping and evolution in mountainous areas throughout time, and (ii) the significance of long term landslide monitoring as a base for the compilation of a landslide inventory and hazard analysis and assessment.

Author Contributions

Conceptualization, Aspasia Litoseliti and Ioannis K. Koukouvelas; Methodology, Aspasia Litoseliti and Ioannis K. Koukouvelas; Software, Aspasia Litoseliti and Konstantinos G. Nikolakopoulos; Field Work, Aspasia Litoseliti, Ioannis K. Koukouvelas, Konstantinos G. Nikolakopoulos, and Vasiliki Zygouri; Data Curation, Aspasia Litoseliti, Ioannis K. Koukouvelas, and Konstantinos G. Nikolakopoulos; Writing-Original Draft Preparation, Aspasia Litoseliti; Writing-Review and Editing, Aspasia Litoseliti, Ioannis K. Koukouvelas, Konstantinos G. Nikolakopoulos, and Vasiliki Zygouri. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Acknowledgments

The authors would like to express their gratitude to the three anonymous reviewers for their constructive and helpful comments that substantially improved the manuscript. This work was partly supported by grant E078 from the Research Committee of the University of Patras to IK and VZ (Program K. Karatheodori). In addition, we acknowledge the careful English language editing by George Kostiras, Professor of English Literature.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. (a) Location map and (b) shaded relief map of the study area; (c) Slope map of Skolis Mountain.
Figure 1. (a) Location map and (b) shaded relief map of the study area; (c) Slope map of Skolis Mountain.
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Figure 2. An example of the changes to landslide areas identified from the orthophotos. The orthophotos show, from (ad), the perimeter of the digitized polygon area. Asymmetrical crosses (in black) represent the evolution of length and width that appeared in Figure 4.
Figure 2. An example of the changes to landslide areas identified from the orthophotos. The orthophotos show, from (ad), the perimeter of the digitized polygon area. Asymmetrical crosses (in black) represent the evolution of length and width that appeared in Figure 4.
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Figure 3. Flow chart that shows the steps of our methodology.
Figure 3. Flow chart that shows the steps of our methodology.
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Figure 4. (a) Definitions of geometric parameters of Skolis Mtn landslides and the minimum bounding rectangle method; (b) Histogram showing the landslide spatial distribution in Skolis Mtn in terms of the crest height; (c) Plot showing the landslides aspect ratio during 2017. The solid black lines represent the best fit line between the length and width of the three landslide types of the table. (d) Chart showing the number (bars) and the cumulative number of landslides (dots) in the 1945–2017 time intervals. The stars show the earthquake events that appeared in Figure 8c. For the date of each earthquake, see Figure 8c.
Figure 4. (a) Definitions of geometric parameters of Skolis Mtn landslides and the minimum bounding rectangle method; (b) Histogram showing the landslide spatial distribution in Skolis Mtn in terms of the crest height; (c) Plot showing the landslides aspect ratio during 2017. The solid black lines represent the best fit line between the length and width of the three landslide types of the table. (d) Chart showing the number (bars) and the cumulative number of landslides (dots) in the 1945–2017 time intervals. The stars show the earthquake events that appeared in Figure 8c. For the date of each earthquake, see Figure 8c.
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Figure 5. The evolution of the 21 landslides mapped from the orthomosaics during the 1945–2017 close to the Santomerion Village.
Figure 5. The evolution of the 21 landslides mapped from the orthomosaics during the 1945–2017 close to the Santomerion Village.
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Figure 6. Map of length and width evolution of the 21 landslides appeared in Figure 5, in the Santomerion area. Crosses show dimensions of pre-earthquake landslide and their evolution over time. Asymmetrical crosses represent their inflation and/or enlargement, double crosses indicate coalescence of two or more landslides due to earthquake activity: (a) The orange rectangles show the newly formed landslides. The green rectangles show the evolved pre-earthquake landslides; (b) Mapping of the inflation and/or enlargement of 2008 earthquake triggered or reactivated landslides. The dark color indicates inflated and/or enlarged landslides after the 2008 earthquake, while the blur suggests more or less stable landslides.
Figure 6. Map of length and width evolution of the 21 landslides appeared in Figure 5, in the Santomerion area. Crosses show dimensions of pre-earthquake landslide and their evolution over time. Asymmetrical crosses represent their inflation and/or enlargement, double crosses indicate coalescence of two or more landslides due to earthquake activity: (a) The orange rectangles show the newly formed landslides. The green rectangles show the evolved pre-earthquake landslides; (b) Mapping of the inflation and/or enlargement of 2008 earthquake triggered or reactivated landslides. The dark color indicates inflated and/or enlarged landslides after the 2008 earthquake, while the blur suggests more or less stable landslides.
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Figure 7. (a) Table of aspect ratios of landslide types at Skolis Mtn; (b) Plot showing the temporal increase of the length or the width of the I- and J-type slides at Santomerion village.
Figure 7. (a) Table of aspect ratios of landslide types at Skolis Mtn; (b) Plot showing the temporal increase of the length or the width of the I- and J-type slides at Santomerion village.
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Figure 8. (a) Map of epicenter distribution in the Skolis Mtn area for the period. The map is extracted from Figure 4. 0 ≤ Mw ≤ 4.5 events, the blue show the epicenters of 4.6 ≤ Mw ≤ 5.0 events, the green show the epicenters of the 5.1 ≤ Mw ≤ 5.5 events, the orange shows the epicenters of 5.6 ≤ Mw ≤ 6.0 events, and the yellow dots show the epicenters of 6.1 ≤ Mw ≤ 6.5 events. The plotted events affected the landslide distribution and contributed to their evolution as deduced by the Arias intensity calculation. Sa: Santomerion village; (b) Diagram of Arias intensities, provided by Equation (1) and seismic magnitudes that affected Skolis area from 1945–2017. (c) The table presents the critical events that affected the studied area. The last years of 2016–2017 show no seismicity.
Figure 8. (a) Map of epicenter distribution in the Skolis Mtn area for the period. The map is extracted from Figure 4. 0 ≤ Mw ≤ 4.5 events, the blue show the epicenters of 4.6 ≤ Mw ≤ 5.0 events, the green show the epicenters of the 5.1 ≤ Mw ≤ 5.5 events, the orange shows the epicenters of 5.6 ≤ Mw ≤ 6.0 events, and the yellow dots show the epicenters of 6.1 ≤ Mw ≤ 6.5 events. The plotted events affected the landslide distribution and contributed to their evolution as deduced by the Arias intensity calculation. Sa: Santomerion village; (b) Diagram of Arias intensities, provided by Equation (1) and seismic magnitudes that affected Skolis area from 1945–2017. (c) The table presents the critical events that affected the studied area. The last years of 2016–2017 show no seismicity.
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Figure 9. (a) Correlation between dates, minimum, maximum, and mean area of studied landslides from 1945 to 2017. The insert shows the minimum area distribution in a larger scale; (b) The cumulative percentage of landslide number is plotted against the cumulative percentage of landslide area; (c) Regression analysis using the log-log scale. The coefficient of determination, R2, denotes the strength of the linear association between the cumulative number of landslides and area.
Figure 9. (a) Correlation between dates, minimum, maximum, and mean area of studied landslides from 1945 to 2017. The insert shows the minimum area distribution in a larger scale; (b) The cumulative percentage of landslide number is plotted against the cumulative percentage of landslide area; (c) Regression analysis using the log-log scale. The coefficient of determination, R2, denotes the strength of the linear association between the cumulative number of landslides and area.
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Figure 10. Landslide density and landslide area percentage versus date. The columns represent the landslide density and the dots the landslide area percentage. The labels on the columns indicate the extent of the affected area.
Figure 10. Landslide density and landslide area percentage versus date. The columns represent the landslide density and the dots the landslide area percentage. The labels on the columns indicate the extent of the affected area.
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Figure 11. Relationship between horizontal length (L) and change in elevation/height (H): Black dashed line: Dai and Lee [60]; Green line: Xu et al. [62]; Red bold line: linear fit that corresponds to the present event-based landslide inventory; Grey dashed line: Qi et al. [62].
Figure 11. Relationship between horizontal length (L) and change in elevation/height (H): Black dashed line: Dai and Lee [60]; Green line: Xu et al. [62]; Red bold line: linear fit that corresponds to the present event-based landslide inventory; Grey dashed line: Qi et al. [62].
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Figure 12. (a) Maximum runout distance of landslides: the reach angle of 33.6° indicates the slope angle on which most earthquake-induced landslides in this area generally occur (see Section 7.1 for additional explanation). (b) Landslide hazard zonation of the Skolis Mtn. The rate of risk corresponds to the proximity to residential areas.
Figure 12. (a) Maximum runout distance of landslides: the reach angle of 33.6° indicates the slope angle on which most earthquake-induced landslides in this area generally occur (see Section 7.1 for additional explanation). (b) Landslide hazard zonation of the Skolis Mtn. The rate of risk corresponds to the proximity to residential areas.
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Figure 13. The table and the chart illustrate the results of estimated RL for each landslide site in the Santomerion area from 1945–2017.
Figure 13. The table and the chart illustrate the results of estimated RL for each landslide site in the Santomerion area from 1945–2017.
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Figure 14. Hazard map of the area between Portes in the south and Santomerion villages in the north.
Figure 14. Hazard map of the area between Portes in the south and Santomerion villages in the north.
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Table 1. Seismicity and spatial resolution of the analogue aerial photographs (AAP), digital aerial photographs (DAP), and satellite images (SI) datasets used and their sources. Orange color represent periods of available aerial photographs and light green the lack of aerial photographs.
Table 1. Seismicity and spatial resolution of the analogue aerial photographs (AAP), digital aerial photographs (DAP), and satellite images (SI) datasets used and their sources. Orange color represent periods of available aerial photographs and light green the lack of aerial photographs.
Date *Seismicity PeriodsData TypeSourcePhotos NumberSpatial Resolution
1945NO SEISMICITYAAP 1HMGS 221 m
1960AAPHMGS21 m
1973AAPHMGS11 m
1987AAPHMGS41 m
1988SEISMICITYNO AQUISITION OF AERIAL PHOTOGRAPHS
1993
1994NO SEISMICITY
1996OrthomosaicsHMGS 1 m
2002NO AQUISITION OF AERIAL PHOTOGRAPHS
2003SEISMICITY
2004NO SEISMICITY
2006
2007SEISMICITYAAP/SI 3HMGS, GΕ 42, 11 m
2008DAP 5 orthomosaic, field mapping, SINGCMA 6 and GE10.5 m
2009SI10.65 7 m
2010NO SEISMICITYNO AQUSITION OF AERIAL PHOTOGRAPHS
2011SEISMICITY
2012NO SEISMICITY
2014
2015SEISMICITYSIGE10.65 m
2016NO SEISMICITYNO AQUSITION OF AERIAL PHOTOGRAPHS
2017SIGE1m
* Orange shading is for dates of orthomosaiscs. 1 AAP = Analogue aerial photographs; 2 HMGS = Hellenic Military Geographical Service; 3 SI = satellite images; 4 GE = Google Earth; 5 DAP = Digital aerial photographs; 6 NGCMA = National Greek Cadaster and Mapping Agency; 7 High resolution-imagery provided by satellite constellation of DigitalGlobe Tables may have a footer.
Table 2. Statistical parameters of the studied landslide sites on the west bluff of Skolis Mountain.
Table 2. Statistical parameters of the studied landslide sites on the west bluff of Skolis Mountain.
DateNumber of Landslides (N)New Landslides (N)Affected Area (m2)Landslide Area Percentage (%) **Landslide Density (N/km2)Density of New Landslides (N/km2)Interval (yr)Landslide Frequency (N/km2*yr)
194542Reference datum33,4960.8610.77Reference datum
196047536,7410.9412.051.28150.80
197347036,6570.9412.050.00130.93
198749238,0960.9812.560.51140.90
1996722395,6992.4518.465.9092.05
2007 (13 August)753118,0213.0319.230.77111.75
2008 (15 May, 10 July)8914242,1986.2122.823.59122.82
2009 (20 July)890269,1096.9022.820.00122.82
2015 (5 May)890278,9697.1522.820.0063.80
2017 (12 August)890292,9187.5122.820.00211.41
Total8947292,9187.51 72
** The percentage of landslide area is calculated with respect to the total area covered by landslides for the period 1945–2017.
Table 3. Temporal and spatial characteristics of the landslide sites from visual interpretation.
Table 3. Temporal and spatial characteristics of the landslide sites from visual interpretation.
InventoryLandslide Area (m2)
AgeNumber of Landslides (N)Affected Area (m2)MinMaxMeanStd. Dev.
19454233,49650.645456.27957.021108.21
19604736,74158.625499.67918.521121.23
19734736,65758.625499.67916.411118.71
19874938,09658.625500.12917.061119.26
19967295,69958.788197.591519.041864.45
2007 (13 August)75118,02158.808197.891639.171896.02
2008 (15 May, 10 July)89242,198128.1017,344.912984.512990.01
2009 (20 July)89269,109141.0219,937.893293.213321.11
2015 (5 May)89278,969141.0222,692.953170.113716.50
2017 (12 August)89292,918148.0723,827.593328.623902.32
Total89292,918
Table 4. Weight of the landslide hazard in the study area. Green color represents the low hazard, yellow and light orange represent moderate hazard and red and dark red color high hazard.
Table 4. Weight of the landslide hazard in the study area. Green color represents the low hazard, yellow and light orange represent moderate hazard and red and dark red color high hazard.
Rate of Increase/Type0–1.5 m yr−11.5–3 m yr−13–4.5 m yr−1>4.5 m yr−1
Δ1234
J2468
I36912
Rate of increase per year: (1) = 0–1.5 m yr−1, (2) = 1.5–3 m yr−1, (3) = 3–4.5 m yr−1, (4) = >4.5 m yr−1.

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Litoseliti, A.; Koukouvelas, I.K.; Nikolakopoulos, K.G.; Zygouri, V. An Event-Based Inventory Approach in Landslide Hazard Assessment: The Case of the Skolis Mountain, Northwest Peloponnese, Greece. ISPRS Int. J. Geo-Inf. 2020, 9, 457. https://doi.org/10.3390/ijgi9070457

AMA Style

Litoseliti A, Koukouvelas IK, Nikolakopoulos KG, Zygouri V. An Event-Based Inventory Approach in Landslide Hazard Assessment: The Case of the Skolis Mountain, Northwest Peloponnese, Greece. ISPRS International Journal of Geo-Information. 2020; 9(7):457. https://doi.org/10.3390/ijgi9070457

Chicago/Turabian Style

Litoseliti, Aspasia, Ioannis K. Koukouvelas, Konstantinos G. Nikolakopoulos, and Vasiliki Zygouri. 2020. "An Event-Based Inventory Approach in Landslide Hazard Assessment: The Case of the Skolis Mountain, Northwest Peloponnese, Greece" ISPRS International Journal of Geo-Information 9, no. 7: 457. https://doi.org/10.3390/ijgi9070457

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