Abstract
On 18 January 2010, 15:56 UTC, a M w = 5.1 (National Observatory of Athens; NOA) earthquake occurred near the town of Efpalion (western Gulf of Corinth, Greece), about 10 km to the east of Nafpaktos, along the north coast of the Gulf. Another strong event occurred on 22 January 2010, 00:46 UTC with M w = 5.1 (NOA) approximately 3 km to the NE of the first event. We processed the seismological and geodetic data to examine fault plane geometry, dip direction, and earthquake interactions at the western tip of the Corinth rift. Our data include relocated epicenters of 1,760 events for the period January–June 2010 and daily global positioning system observations from the Efpalio station for the period 1 December 2009–1 March 2010. We suggest that the first event ruptured a blind, north-dipping fault, accommodating north–south extension of the Western Gulf of Corinth. The dip direction of the second event is rather unclear, although a south dip plane is weakly imaged in the post-22 January 2010 aftershock distribution. A Coulomb stress model based on homogeneous slip distribution of the first event showed static stress triggering of the second event of the order of 22–34 KPa that was transferred along the plane of failure. We also point out the existence of north dipping, high-angle faults at 10–15 km depths, which were reactivated because of Coulomb stress transfer, to the west and south of Efpalion. The January 2010 earthquakes ended a 15-year-old quiescence in that area of the Gulf. The crustal volume near Efpalion was also characterized by b values in the range 0.6–0.8 (1970–2010 period).
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1 Introduction
On 18 January 2010, 15:56 UTC, a M w = 5.1 (National Observatory of Athens; NOA) moderate earthquake occurred near the town of Efpalion, about 10 km to the east of Nafpaktos, along the north coast of the Gulf of Corinth (Fig. 1, yellow stars). On 22 January 2010, 00:46 UTC, a second event of M w = 5.1 (NOA) occurred a few kilometers to the east of 18 January 2010 event. No casualties or serious damage was reported. Focal mechanism solutions by Sokos et al. (2012) determined east–west striking fault planes with a dominant component of normal slip (strike/dip/rake 102°/55°/−83° and 270°/36°/−100° for the first event; 282°/52°/−75° and 78°/40°/−109° for the second event). This sequence ended a 15-year seismic quiescence in this area of Greece as the last major event was the Aigion (June 1995, M S = 6.2), offshore earthquake about 20 km to the east of Efpalion (Bernard et al. 1997; event 061595A in Fig. 1).
The Efpalion area occupies the north coast of the Gulf of Corinth and comprises Mesozoic–Early Tertiary sedimentary rocks of the so-called External Hellenides tectonic nappes. The thrusts are west verging and of Late Eocene–Oligocene Age. The main structural feature is the contact between the shallow Parnassus unit and the abyssal Pindos unit (Doutsos et al. 2006). Nappe stacking and crustal shortening during most of Tertiary led to formation of thick crust. In particular, the thickness of the continental crust in this area is the highest of central Greece, 40 km (Zelt et al. 2005).
Since Pliocene, this region is one of the most active extensional continental regions in the world, located between the two lithospheric plates of Eurasia and Africa, which converge at a combined rate of about 3–4 cm/year. The geological evidence of normal faulting and the high seismicity, both historical and instrumental, imply a high rate of extension. In particular, the western Gulf of Corinth is a young (Quaternary) graben characterized by fast extension rates (>1.5 cm/year; Briole et al. 2000; Avallone et al. 2004) and high seismicity (e.g., Rigo et al. 1996; Rietbrock et al. 1996; Hatzfeld et al. 1996; Jansky et al. 2004). The last major seismic event occurred on 15 June 1995 at 00:15 UTC when a M S = 6.2 earthquake rupture a low-angle fault offshore Aigion (Fig. 1; Bernard et al. 1997). After the 1995 event, the area was recognized as a site of global tectonic significance where a number of EU research projects have been completed (3F-Corinth, DG-Lab, CRL, CORSEIS, and several others are ongoing (see http://crlab.eu/ for a summary of research activity)). The overall concept of those research projects was that to move progressively towards a research infrastructure for the assessment of the seismic risk in the Gulf of Corinth region and to better understand the role of fluids and stress transfer in the crust and lithosphere and their role in the triggering of earthquakes. Recently, the Gulf of Corinth is included in the list of European Space Agency–Group on Earth Observation supersites (http://supersites.unavco.org/main.php).
Seismic activity inside the Gulf of Corinth was moderate to high following the June 1995 event, with no events with M > 6 occurring inside the Gulf (Fig. 1). During the last 17 years (1995–2012), two shallow seismic sequences have occurred in the vicinity of the western Gulf of Corinth (Fig. 1): (a) the April 2007 earthquake swarm at the eastern end of Trichonis Lake (three events with M = 5.0–5.2, Kiratzi et al. 2008) and (b) the 8 June 2008 Movri mountain event in south Achaia (M = 6.4, Ganas et al. 2009; Gallovic et al. 2009; Koukouvelas et al. 2009). In addition, a M w = 5.0 event occurred on 13 December 2008, near Amfiklia, Central Greece (Chouliaras 2009a, b; Roumelioti and Kiratzi 2008; event 20081213 in Fig. 1).
This paper presents (a) an analysis of seismological data collected by NOA (we gathered 1,760 earthquakes, including the two main seismic events, during the period 18 January–30 June 2010), (b) static processing results from global positioning system (GPS) observations, and (c) results from an earthquake-triggering model (based on static stress transfer) for this sequence. The main points of our findings was to identify the north-dipping plane as the 18 January 2010 slip plane and confirm the existence of north dipping, high-angle faults at 10–15 km depths, which were reactivated because of Coulomb stress transfer, to the west and south of Efpalion. These observations confirm the normal character of earthquake slip to the west of Aigion 1995 earthquake. An additional point is the recognition of nonspatial decay of earthquake magnitude during the early aftershock sequence (18–22 January 2010).
2 Data analysis
2.1 Seismic data
The location parameters of the two main shocks are reported in Table 1. The first, main seismic event occurred on 18 January 2010, with a local magnitude M L = 5.2 (M w = 5.1). It was followed by a second major seismic event at 22 January 2010, with a local magnitude M L = 5.1 (M w = 5.1). We relocated the epicenter of the 18 January 2010 as 38.3962° north, 21.9039° south, with depth of 8.5 km, while the epicenter of the 22 January 2010 is to the NE of the 18 January 2010 and shallower, i.e., 38.4075° north, 21.9422° south, depth of 5.1 km (Fig. 1). All earthquakes were relocated using the HYPOINVERSE (Y2000 version; Klein 2002) and the HYPODD (double difference; Waldhauser 2001) algorithms, in succession. Phase data were available from the permanent seismic network of NOA in HYPO71 (Lee and Lahr 1972) format.
For the region of our interest, we gathered 1,892 earthquakes, including the two main seismic events, during the period 18 January–30 June 2010. The parameters of these earthquakes were initially determined by the algorithm HYPO71, using the 1-D NOA velocity model (Table 2; Fig. 2). V p /V s ratio value used was 1.78. Next step was the relocation of all seismic events with the algorithm HYPOINVERSE. During this procedure, no data were rejected. The main characteristic of HYPOINVERSE that we exploited was that every phase (P and S) is assigned a weight code that indicates the weight that the phase carries to the final solution. After this relocation, considerable changes were observed in the epicenters and the depths of the 1,892 events, therefore, we continue with final part of our project, relocation of the seismic events using the HYPODD algorithm (double-difference earthquake algorithm). The double-difference technique allows the use of any combination of ordinary phase picks from earthquake catalogs and/or high-precision differential travel times from phase correction of P and/or S waves (cross-correlation data). We only have phase picks available from the earthquake catalogs of the National Observatory of Athens. Earthquake relocation with HYPODD is a two-step process. The first step involves the analysis of catalog phase data and/or waveform data to derive travel time differences for pairs of earthquakes. Processing of catalog phase data is done by using the ph2dt procedure.
In the second step, the differential travel time data from step 1 is used to determine double-difference hypocenter locations. This process is carried out by the hypoDD algorithm. For the area of our interest, we have chosen the conjugate gradients method (sparse equations and least squares; Paige and Saunders 1982) and the 1-D velocity model of Tselentis and Zahradnik (2000; referred as Patras model in brief, Table 2). We also tried the velocity models by Latorre et al. (2004) and Rigo et al. (1996) without significant changes in seismicity patterns, so we adopted the so-called Patras velocity model. An important parameter in the hypoDD algorithm which defines the clustering is the OBSCT parameter. This parameter defines the minimum number of catalog links that must be present to form a continuous chain needed to identify a cluster. In our case, we chose OBSCT = 8, which is a typical choice, since it coincides with the number of degrees of freedom for an event pair (three spatial and one time for each event). In the earthquake sequence of 18 January 2010, from the 1,892 earthquakes, relocated by HYPOINVERSE, the 1,867 events were selected by the HYPODD algorithm and 63 stations from the Hellenic Unified Seismological Network (HUSN). The rest of the available stations were rejected since they were considered to be much distanced from the region of our study. This selection is defined by the parameters of the hypoDD algorithm, such as DIST, which shows the maximum distance between centroids of event clusters and stations. We chose DIST = 380 km and we found that a unique cluster was formed, including 1,833 seismic events. The rest, 34 events, were considered as isolated events. By the end of the relocation (Fig. 2), the hypoDD algorithm concluded to 1,760 earthquakes and 63 contributing stations. The rejected events were due to reweighting or some events becoming airquakes.
Two hundred fifty-nine events occurred between 18 January 2010 (15:56 UTC) and 22 January 2010 (00:46 UTC) with 1.9 < M < 4.0. The map and cross-sections in Fig. 3a show the tight distribution of the seismic sequence in space during the first 3.5 days (Fig. 3a). Almost all aftershocks occur to the north and east of the 18 January 2010 main shock at depths of 4–12 km. The pattern of aftershock distribution in map view supports a north-dipping fault (nodal plane with strike/dip/rake 270°/36°/−100°) of Sokos et al. (2012), as it is common in normal-fault earthquakes that most aftershocks occur inside the hanging wall area for example, the 1999 Athens earthquake, (Baumont et al. 2004) and the 2009 L’Aquila earthquake (Chiarabba et al. 2009). The biggest cluster of aftershocks occurred in the hypocentral region of the 22 January 2010 event. This cluster exhibits a vertical structure (looking across strike) which suggests that the aftershocks occur within a highly stressed area to the east of the 18 January 2010 event and not along a particular fault plane. Plotting the entire seismicity (January–June 2010; Fig. 3b), it is seen that earthquakes occurred more to the east than to the west. In addition, the pattern of the 5-month seismicity has a clear east–west orientation, along the north coast of the Gulf of Corinth, which is a result of Coulomb stress loading in this orientation as we show later in this paper. Seismicity cross-sections also show a depth distribution of hypocenters from 4 to 12 km. This depth range defines the seismogenic brittle zone of the crust. In section A1–A2 (Fig. 3b) a 40–50° angle, north-dipping cluster can be identified (shown by a red arrow), which was activated after 22 January 2010 (see Fig. 3a for a comparison). In sections B1–B2 and C1–C2, the clusters develop around the main shock hypocenters and form near-vertical structures. In section B1–B2, we note the existence of a high-angle cluster at depths between 10 and 17 km, with a 50–55° dip angle, The activated fault plane dips to the north and its surface projection lies to the south of the coastal Psathopyrgos fault (also north dipping; Doutsos and Poulimenos 1992; Houghton et al. 2003; Tsimi et al. 2007). This cluster was activated after 22 January 2010, as well. The along-strike seismicity profile defines an overall “trapezoidal” shape with is longest dimension at depth and extending 17 km in the along strike (ESE–WNW) direction. Figure 3c presents a larger-scale overview of the aftershock distribution (period 22 January–30 June 2010), where while reproducing the Fig. 3b features, it shows in better detail: (a) a south-dip imaged fault in the vicinity of the 22 January 2010 hypocenter (Fig. 3c, section C1–C2) in the depth range of 3–6 km; (b) moderate to high-angle, north-dipping faults in the range of depths of 7–12 km; (c) end of seismicity at depths larger than 12 km.
2.2 Geodetic data
We analyzed daily observations of the permanent GPS station EYPA near Efpalion, operated by Institut National des Sciences de l’Univers for the period 1 December 2009–1 March 2010 (Fig. 4). Code and phase data were processed with GAMIT/GLOBK software package (Herring et al. 2006). We included in our analysis data from 18 additional IGS stations (BRUS, CAGL, GRAZ, HERS, KIT3, MAS1, METS, PDEL, POL2, POTS, RABT, TRO1, WTZR, ZIMM, NICO, BUCU, ISTA, TELA) in order to serve as ties with the International Terrestrial Reference Frame 2005 (ITRF05; Altamimi et al. 2007). GAMIT uses double-differenced phase measurements (ionosphere-free linear combinations of the L1 and L2) to generate weighted least squares solutions for each daily session. Estimated parameters include station coordinates, the six orbital elements for each satellite, Earth orientation parameters, and integer phase ambiguities. An automatic cleaning algorithm was applied to post-fit residuals in order to repair cycle slips and to remove outliers. The observation weights vary with elevation angle and are derived individually for each site from the scatter of post-fit residuals obtained in a preliminary GAMIT solution. We used a 10° elevation cutoff angle and atmospheric zenith wet delays were estimated every 2 h. We used the IGS absolute antenna phase center table for modeling the effective phase center of the receiver and satellites antennas and we applied the FES2004 ocean tide-loading model. The atmospheric propagation delay was modeled by means of Vienna mapping functions 1 (Boehm et al. 2006), and solid earth and polar tide corrections following the IERS/IGS standard 2003 model (McCarthy and Petit 2004). We used orbits provided (as g-files) by the Scripps Orbit Permanent Array Center (SOPAC). Next, the loosely constrained estimates and their covariances from each day were used as quasi-observations in GLOBK Kalman filter and combined with global and regional IGS and EUREF loosely constrained solutions provided by SOPAC. The reference frame was defined in the final step, applying generalized constraints while estimating a six-parameter transformation (six components of the rate of change of translation and rotation) by minimizing the departure of the horizontal velocities of the previously mentioned IGS sites from their a priori values given in the International Terrestrial Reference Frame 2005 (ITRF05). The final product of the analysis is three-component time series of daily station positions with respect to ITRF05.
The daily solutions of the static processing for the days before and after of the two events are reported in Table 3 (also in Fig. 4 in graphic form). Two coseismic offsets were detected corresponding to the 18–22 January 2010 earthquakes. To estimate the static coseismic displacements separately for the two events, we calculated the difference between the average position of 7 days before and 3 days after the earthquake of 18 January and the difference between the average position of 3 days before and 7 days after the event of 22 January. The displacements that occurred during the first event were 0.46 cm to the south, 0.51 cm to the east, and 1.73 cm downwards; while during the second event were 0.15 cm to the north, 0.35 cm to the east, and 1.84 cm downwards. These coseismic offsets are of the same order of magnitude, except for the north–south component where the second event caused very small displacement to the north, in contrast to the offset of the first event. We estimated the total, average static displacement for both events, by fitting a line through the data points before and after the two mainshocks (Fig. 4, dotted red line). The total offset is 0.29 cm towards the south, 0.85 cm to the east, and 3.71 cm downwards (i.e., subsidence). 1 − σ errors are 0.2 cm (north–south), 0.1 cm (east–west), and 0.5 cm (up–down), respectively. We note that the vertical displacement was accumulated through small offsets on 19, 20, and 21 of January 2010, respectively. Figure 5 shows the total motion of station EYPA from 17 to 22 January 2010. During the first event, the station moved to the SE. In the period between the two events, a small motion to the west is detected (about 1 mm). During the second event, the station moved to the NE with respect to its 18 January coseismic position. The overall motion was to the SE.
3 Coulomb stress modeling
Earthquakes have been observed to trigger subsequent earthquakes at short distances from the hypocenter by transferring static or dynamic stresses (e.g., Harris et al. 1995; Gomberg et al. 2001; Freed 2005; Parsons et al. 2006). We model stress transfer assuming that failure of the crust occurs by shear so that the mechanics of the process can be approximated by the Okada (1992) expressions for the displacement and strain fields due to a finite rectangular source in an elastic, homogeneous, and isotropic half space. In this paper, we compute the Coulomb stress change by assuming a shear modulus of 3 × 1010 Pa, Poisson’s ratio 0.25, and two effective coefficients of friction (μ′ = 0.4 and μ′ = 0.1). We studied two cases of effective coefficient of friction: μ′ = 0.4, which is closer to friction values for major faults (Harris and Simpson 1998) and μ′ = 0.1, which is closer to friction values on faults developed in weaker rheology. Details of the methodology can be found in previous works such as Ganas et al. (2008, 2010).
We calculated the change in the Coulomb failure function (CFF or Coulomb stress), on target failure planes (Reasenberg and Simpson 1992),
where Δτ is the coseismic change in shear stress on the receiver fault and in the direction of fault slip, Δση is the change in the normal stress (with tension positive) and μ′ is the effective coefficient of friction,
where μ is the coefficient of static friction and ΔΡ is the pore pressure change within the fault. From (2) it follows that, if ΔP = 0 then μ' = μ. ΔCFF is the Coulomb stress change between the initial (ambient) stress and the final stress. If the dislocation model (Table 4) is thought of as an earthquake rupture, the ambient field is the field that existed before the earthquake and the total field is the sum of the ambient field plus the earthquake-induced stresses.
3.1 Triggering of the 22 January 2010 earthquake
We computed Coulomb stress change caused by the 18 January 2010 event on optimally oriented planes to regional extension. A value of 20 MPa was adopted as regional stress magnitude to provide a stress level well above the average static stress drop of moderate–large earthquakes (3–4 MPa; Kanamori and Anderson 1975; Allman and Shearer 2009). For extension azimuth, we adopted the orientation of the T axis of the focal plane solution of the 18 January 2010 event (N187° E; Table 4). The calculation was done at seismogenic depths (5–11 km range) including the depth of the 22 January 2010 event hypocenter (5 km). The target planes are similar in orientation to the 18 January 2010 fault plane, i.e., they strike east–west and dip either to the north or to the south. Next, we run elfgrid to calculate the stress tensor on horizontal observation planes. The output is six grids, one for each component of the tensor. Then, we calculate the change in the CFF on optimal failure planes at 5–11 km range of depths by running stroop (stress_on_optimal_planes). ΔCFF was sampled on a 20 × 20 km grid, with 0.5 km grid spacing. A uniform slip model provided by Sokos et al. (2011, 2012) was used. As a slip surface, we assumed a square, planar source with dimensions 3 × 3 km and a uniform slip of 0.21 m. This set of parameters provides a seismic moment of 5.67 × 1023 dyn cm which is very close to the moments calculated by both NOA (5.59 × 1023 dyn cm) and AUTH (8.49 × 1023 dyn cm). The catalog of the aftershocks used for investigating seismicity triggering was produced by relocation of HUSN events (Fig. 3).
For the 18 January 2010 earthquake, we estimated an average, right-lateral strike-slip displacement (u s ) of 0.036 m and a dip-slip displacement (u d ) of 0.206 m for a magnitude M w =5.1-5.2, by using the Hanks and Kanamori formula (1979):
where M o is the scalar moment of the best double couple in dyne centimeter. Seismic moment is given by the following equation:
where A is fault area, G is shear modulus and u is total displacement. We assumed an asperity of 9 km2 (3 × 3 km wide rupture) which is close to what was suggested by Sokos et al. (2011), who used a slip inversion method. The two components of displacement vector are calculated from the following formulas given the slip models in Table 6:
The parameters considered for the stress change computation are given in Table 5, while the stress change maps are presented in Fig. 6.
The stress change was computed for two cases for the coefficient of apparent friction: 0.1 (Fig. 6a, top) and 0.4 (Fig. 6b, bottom) to account for possible differences on the material properties along the fault planes. We found no significant difference on stress patterns; however, the actual stress values are larger for friction = 0.4. In both cases, Coulomb stress increases laterally (i.e., along the 18 January 2010 rupture) and decreases orthogonally (i.e., across the rupture). At 7–10 km depth, Coulomb stress load exceeds 350 KPa near rupture tips. Most (over 80 %) relocated aftershocks in the depth range of 5–10 km are located inside loaded areas. We also constructed cross-sections of Coulomb stress-oriented north–south to get a 3-D view of the stress field normal to the 18 January 2010 rupture (Fig. 7). The cross-sections show loading of the crust above and below the rupture. We observe that many, off-fault 18–22 January relocated aftershocks occurred inside loaded areas of the upper crust and to the down-dip direction (Fig. 7 top). The aftershocks are occupying mostly a vertical volume of material and occur at distances as much as 6–8 km from the 18 January hypocenter (Fig. 7). Aftershocks occurring inside the relaxed area (both north and south of the seismic fault; right and left from the fault plane depicted in Fig. 7 top) are not explained by our slip model but could be due to (a) missed heterogeneous slip that modifies the static stress transfer change across the fault, (b) on damage in the vicinity of the rupture (brittle microcracking), (c) dynamic stress triggering (Gomberg et al. 2001), or the location uncertainty of the catalog (Catalli and Chan 2012). The stress section going through the 22 January 2010 (Fig. 7b) shows that this area received a Coulomb stress of circa 34 KPa so it was brought closer to failure. We interpret the occurrence of the 22 January 2010 main shock as a result of static triggering by the 18 January 2010 event.
As a variation, Coulomb stress can be calculated on planes of fixed orientation if it is known that there is a fabric of existing normal faults in the western Gulf of Corinth area which are likely to provide planes of failure. In this case, we assume that east–west striking, south-dipping normal faults of the 22 January 2010 type of rupture will be of interest as candidates for failure. We use strop (stress_on_planes) in this run to calculate Coulomb stress on planes of specified orientation at 5–11 km depth (Fig. 6c). We found that triggering is also promoted as the ΔCFF values were positive in the hypocentral area of the 22 January 2010 earthquake (between 22 and 31 KPa; see Table 5). This result further supports our proposal that the 22 January 2010 earthquake in Efpalio was promoted by the 18 January 2010 event.
4 Discussion
4.1 Seismic fault modeling
The geodetic results were examined for identifying the source of deformation. For the 18 January 2010 event, the results of the GPS processing showed a coseismic displacement of 0.45 cm towards the south, 0.51 cm towards the east, and 1.73 cm subsidence (Table 7). The offsets for the 22 January 2010 event are 0.14, 0.34, and 1.89 cm, respectively. We compare these results with forward models for surface deformation in an elastic half-space based on Okada (1992) and using as inputs the focal plane solutions for both events provided by Sokos et al. (2012). Due to the 500-m grid size of our elastic model, we could compare a point located about 300 m from the GPS site. Station GPS EYPA is located at 38.4268 N, 21.9281E while our forward model point is located at 38.4247169 N, 21.9262409E, i.e., ΔL = 0.2826 km. We find that the worst performance is given by the combination of a south-dipping fault for the first event and a north-dipping fault for the second event (Table 3; this was suggested by Sokos et al. 2012). The other two models (a north-dipping fault for the first event and a south-dipping fault for the second event or a south-dipping fault for the first event and a south-dipping fault for the second event) perform almost equally with submillimeter differences. However, both these two slip models underestimate the surface displacements in components u2 (east–west) and u3 (vertical; Table 3). The east–west modeled components are a factor of 10 less than GPS values while the up–down component is less by a factor of 5. This discrepancy is due to either (a) the isotropic and elastic structure of the upper crust assumed in the forward model, (b) the uniform slip model used, or (c) a combination of both. So, in this respect, the GPS static displacements are inconclusive of the geometry of the 18–22 January 2010 fault planes.
However, our relocated seismicity data (Fig. 3) suggests that the first event ruptured a blind, north-dipping normal fault beneath the north shore of the Gulf, near Efpalio because of the preferential location of the aftershock hypocenters in the hangingwall area of the north-dipping imaged fault (see B1–B2 cross-section in Fig. 3a), irrespective of the velocity model used in relocation (i.e., Patras, Latorre et al. 2004; Rigo et al. 1996). The dip attribute is not well constrained by the relocation and it may attain a value between 36° and 48° (see Table 6 for a summary of focal plane solutions). A similar conclusion was reached by Karakostas et al. (2012). The second event (22 January 2010) occurred on a different normal fault, also blind, but not easy to image its geometry from our datasets. The only evidence available is the post-22 January 2010 aftershock pattern aligned along a south-dipping fault in section C1–C2 of Fig. 3c. Karakostas et al. (2012) suggest a north-dipping fault hosting the second event as well.
It is also interesting to point out the existence of north-dipping, high-angle faults at 10–15 km depths, which were reactivated because of Coulomb stress transfer, to the west and south of Efpalion (see A1–A2/B1–B2 cross-sections in Fig. 3b and section F1–F2 in Fig. 3c). This evidence may be considered in the investigations on the nature of extension in this area and on the importance of high-angle faulting in active deformation (e.g., Bell et al. 2009, 2011; Vassilakis et al. 2011; Taylor et al. 2011; Fig. 1).
4.2 Seismicity rate patterns in the western Gulf of Corinth
The occurrence of the 2010 events signifies the end of the seismic quiescence in this area of the Gulf of Corinth so we conducted a statistical analysis of the regional earthquake catalog to search for rate anomalies. For this task, we analyzed the NOA catalog data (spanning a period of 40 years) in order to investigate seismicity rate changes and associated stress levels (e.g., Wyss et al. 2008). The recently compiled earthquake catalog for the 37.00–39.00 N and 19.00–23.50 E regions from 1964 until 2008 (Chouliaras 2009b) was used. Here, we follow the same methodology as in Chouliaras (2009a, b), using the ZMAP software package (Wiemer 2001) and found that in this area of Greece and for depths of 0–50 km, our catalog has a magnitude of completeness of 3.0 ± 0.1 (M c ; Wiemer and Wyss 2000). We also applied the declustering algorithm of Reasenberg (1985) to remove aftershocks and swarms.
Our analysis (Fig. 8) shows that the 2010 Efpalio earthquakes are located inside a relatively low b value area inside the western Gulf of Corinth (b ranges from 0.6 to 0.8 near Efpalion, while the value for the total NOA catalog is 1.14; Chouliaras 2009b). The b value is the slope of the linear fit to the frequency–magnitude distribution of earthquakes [log10 N = a – bM; Gutenberg and Richter 1944]. It describes the relative size of the seismic events and in this paper it was determined by the maximum-likelihood technique following Aki (1965). The b value exhibits heterogeneities in time and space, depending on the stress patterns and in this way it acts as a stress meter (Schorlemmer et al. 2005) where low b values indicate high-stress regimes (Wyss et al. 2008). We find reasonable to associate the 15-year-old quiescence to the low b value of the Efpalion crust, although we cannot estimate its depth dependence. In the western Gulf of Corinth, a low b value was also found by Wyss et al. (2008) for depths greater than 8 km, using a local seismicity catalog.
4.3 Magnitude scaling properties of aftershocks
The energy properties of the aftershock sequence are also important. It is interesting to note that for the first 259 well-located events of the aftershock sequence (18–22 January 2010; Fig. 3a) no scaling is observed between earthquake (aftershock) size and distance to main shock, over 3 orders of magnitude (Fig. 9). Earthquake size ranges for 1.9 < M < 4.1 and distance to main shock from 0.05 < L < 8.18 km. We find no spatial decay of local earthquake magnitude over nearly 2.5 fault lengths with respect to the 18 January 2010 seismic fault (we used a homogeneous slip model 3 × 3 km; Table 4). This observation may favor a dynamic stress transfer triggering mechanism (Felzer and Brodsky 2006) for most of the first 4-day aftershocks versus a static stress triggering scenario where a magnitude scaling with distance would fit the decay of radiated seismic strains, although a more detailed statistical analysis is necessary to clarify this point.
5 Conclusions
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1.
The 18 January 2010, 15:56 UTC M w = 5.1 (NOA) Efpalio event ruptured a blind normal fault which transferred 22–34 KPa Coulomb stress to trigger the 22 January 2010, 00:46 UTC M w = 5.1 (NOA) event, about 3 km to the NE.
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2.
The two M = 5.1 events produced combined, permanent static displacement of station EYPA (Efpalio) of 0.3 cm towards the south, 0.8 cm to the east and 3.6 cm downwards (i.e., subsidence).
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3.
The early aftershock pattern (Fig. 3) favors an 18 January 2010 seismic fault dipping to the north. The post-22 January 2010 aftershock pattern is dispersed with limited evidence for a south-dipping fault at depths 3–7 km in the vicinity of the 22 January 2010 hypocenter.
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4.
We also point out the existence of north-dipping, high-angle faults at 10–15 km depths, which were reactivated because of Coulomb stress transfer, to the west and south of Efpalion.
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5.
The 2010 Efpalio events occurred in a low b value area (0.6–0.8) of the Gulf of Corinth that may be identified with a high concentration of crustal stress.
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6.
The 4-day aftershock sequence (period between 18 and 22 January 2010) shows no spatial decay of magnitude with distance from main shock, over 2.5 fault lengths.
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Acknowledgments
We thank E. Sokos for discussions and Institut National des Sciences de l’Univers/ENS for providing the 30-s rinex files for the Efpalio station. X. Ventouzi helped with HypoDD processing. We acknowledge Bob Simpson for making available the DLC code, Ioannis Kalogeras, Tom Herring and Tom Parsons for useful comments. We thank three anonymous reviewers and the Associate Editor for extensive reviews. The open-source software GMT http://www.soest.hawaii.edu/gmt/ was used to make figures. The GPS data were downloaded from https://gpscope.dt.insu.cnrs.fr/chantiers/corinthe/. We dedicate this paper to the memory of our student Yannis Adamis who passed away on April 5, 2010.
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Ganas, A., Chousianitis, K., Batsi, E. et al. The January 2010 Efpalion earthquakes (Gulf of Corinth, Central Greece): earthquake interactions and blind normal faulting. J Seismol 17, 465–484 (2013). https://doi.org/10.1007/s10950-012-9331-6
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DOI: https://doi.org/10.1007/s10950-012-9331-6