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4. Induced micro seismicity due to raising mine water level in former coal mines in the eastern Ruhr area (Germany)

Author

Felix Allgaier, M. Rische, Wolfgang Friederich, and Kasper D. Fischer

Subjects
geography, Microseism, geography.geographical_feature_category, business.industry, Coal mining, Magnitude (mathematics), Transform fault, Induced seismicity, Fault (geology), Water level, Pore water pressure, Mining engineering, business, Geology
Abstract

FloodRisk is an interdisciplinary project focusing on the effects of mine water level rise in abandoned coal mine regions in Germany. Such effects are heterogeneous ground uplift, stress changes due to the change in pore pressure and the reactivation of potential faults. One of the most directly measurable effects is certainly the induced micro seismicity. It is known from previous studies that the flooding of old mines can lead to a renewed increase level in induced micro seismicity in these regions.In this study the relationship between mine water rise, fluid-induced stress changes and induced seismicity in the Haus Aden dewatering area in the eastern Ruhr area (Germany) will be investigated in more detail. For this purpose, we operate a network of currently 21 short period seismic stations in the region of the former "Bergwerk Ost" colliery, which had the highest seismicity rate in the Ruhr area during active underground coal mining. This network is still to be expanded to cover the entire water drainage area, about 30 Raspberry Shake sensors are waiting for the possibility of installation. Nevertheless, the existing network registered almost 1000 induced micro seismic events in a magnitude range from -0.7 up to 2.6 MLv. Many of these events are spatially clustered and some show quite high waveform similarity. This allows relative localisation and can increase the accuracy of the location. The depth location of the earthquakes, within the limits of localisation accuracy, agrees very well with the distribution of seismicity at the time of active mining. The spatial distribution so far seems to be limited by a large inactive transverse fault in the west. It needs to be clarified what influence this fault has on the propagation of mine water in the underground.The measured temporal trend of the mine water level, after pumps were shut down in mid-2019, shows a strong correlation with the temporal evolution of the observed micro seismicity. In the first months after the pumps are switched off, the water levels at the observation points rise only slowly and isolated microseismic events occur again. In November 2019, the rise in water levels doubled and at the same time, the strongest induced event in the measurement period was recorded with a magnitude of 2.6 MLv. In the following months, the seismicity rate ranged from 8 to 34 events above 0.5 MLv per month, some of which were felt. A structural geological 3D subsurface model is developed to help to understand the distribution of induced seismicity and the role of the raising mine water level.

Published
2021

5. Tearing, segmentation, and backstepping of subduction in the Aegean: New insights from seismicity

Author

Gian Maria Bocchini, Wolfgang Friederich, A. Brüstle, Dirk Becker, Marija Ruscic, Gerassimos A. Papadopoulos, M. Rische, P. E. van Keken, and Thomas Meier

Subjects
Hellenic arc, 010504 meteorology & atmospheric sciences, Subduction, Transform fault, Induced seismicity, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Discontinuity (geotechnical engineering), Lithosphere, Trench, Slab, Geology, Seismology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

This study revisits subduction processes at the Hellenic Subduction Zone (HSZ) including tearing, segmentation, and backstepping, by refining the geometry of the Nubian slab down to 150–180 km depth using well-located hypocentres from global and local seismicity catalogues. At the western termination of the HSZ, the Kefalonia Transform Fault marks the transition between oceanic and continental lithosphere subducting to the south and to the north of it, respectively. A discontinuity is suggested to exist between the two slabs at shallow depths. The Kefalonia Transform Fault is interpreted as an active Subduction-Transform-Edge-Propagator-fault formed as consequence of faster trench retreat induced by the subduction of oceanic lithosphere to the south of it. A model reconstructing the evolution of the subduction system in the area of Peloponnese since 34 Ma, involving the backstepping of the subduction to the back-side of Adria, provides seismological evidence that supports the single-slab model for the HSZ and suggests the correlation between the downdip limit of the seismicity to the amount of subducted oceanic lithosphere. In the area of Rhodes, earthquake hypocentres indicate the presence of a NW dipping subducting slab that rules out the presence of a NE-SW striking Subduction-Transform-Edge-Propagator-fault in the Pliny-Strabo trenches region. Earthquake hypocentres also allow refining the slab tear beneath southwestern Anatolia down to 150–180 km depth. Furthermore, the distribution of microseismicity shows a first-order slab segmentation in the region between Crete and Karpathos, with a less steep and laterally wider slab segment to the west and a steeper and narrower slab segment to the east. Thermal models indicate the presence of a colder slab beneath the southeastern Aegean that leads to deepening of the intermediate-depth seismicity. Slab segmentation affects the upper plate deformation that is stronger above the eastern slab segment and the seismicity along the interplate seismogenic zone.

Published
2018

6. Seismicity and active tectonics at Coloumbo Reef (Aegean Sea, Greece): Monitoring an active volcano at Santorini Volcanic Center using a temporary seismic network

Author

E. Karagianni, Panagiotis Hatzidimitriou, C. B. Papazachos, I. Dimitriadis, M. Rische, Marco Bohnhoff, Thomas Meier, and D. G. Panagiotopoulos

Subjects
geography, geography.geographical_feature_category, Volcanic arc, 550 - Earth sciences, Fracture zone, Fault (geology), Tectonics, Geophysics, Volcano, Seismic array, Caldera, Submarine volcano, Seismology, Geology, Earth-Surface Processes
Abstract

The volcanic center of Santorini Island is the most active volcano of the southern Aegean volcanic arc. Α dense seismic array consisting of fourteen portable broadband seismological stations has been deployed in order to monitor and study the seismo-volcanic activity at the broader area of the Santorini volcanic center between March 2003 and September 2003. Additional recordings from a neighbouring larger scale temporary network (CYCNET) were also used for the relocation of more than 240 earthquakes recorded by both arrays. A double-difference relocation technique was used, in order to obtain optimal focal parameters for the best-constrained earthquakes. The results indicate that the seismic activity of the Santorini volcanic center is strongly associated with the tectonic regime of the broader Southern Aegean Sea area as well as with the volcanic processes. The main cluster of the epicenters is located at the Coloumbo Reef, a submarine volcano of the volcanic system of Santorini Islands. A smaller cluster of events is located near the Anydros Islet, aligned in a NE–SW direction, running almost along the main tectonic feature of the area under study, the Santorini–Amorgos Fault Zone. In contrast, the main Santorini Island caldera is characterized by the almost complete absence of seismicity. This contrast is in very good agreement with recent volcanological and marine studies, with the Coloumbo volcanic center showing an intense high-temperature hydrothermal activity, in comparison to the corresponding low-level activity of the Santorini caldera. The high-resolution hypocentral relocations present a clear view of the volcanic submarine structure at the Coloumbo Reef, showing that the main seismic activity is located within a very narrow vertical column, mainly at depths between 6 and 9 km. The focal mechanisms of the best-located events show that the cluster at the Coloumbo Reef is associated with the “Kameni–Coloumbo Fracture Zone”, which corresponds to the western termination of the major ENE–WSW Santorini–Amorgos Fault Zone. Stress–tensor inversion of the available fault plane solutions from Coloumbo Reef, as well as existing neotectonic fault information from NE Santorini (Coloumbo peninsula), suggests that the NE Santorini–Coloumbo faults belong to a single rupture system, with a ~ 30° rotation of the local stress field with respect to the NNW–SSE regional extension field of the southern Aegean Sea. The observed change of the fault plane solutions shows that local conditions at the Coloumbo submarine volcano area control the observed faulting pattern.

Published
2009

8. Microseismic activity in the Hellenic Volcanic Arc, Greece, with emphasis on the seismotectonic setting of the Santorini–Amorgos zone

Author

M. Rische, G. Stavrakakis, Dirk Becker, Thomas Meier, Hans-Peter Harjes, and Marco Bohnhoff

Subjects
geography, geography.geographical_feature_category, Subduction, Volcanic arc, Metamorphic core complex, Transtension, 550 - Earth sciences, Geophysics, Volcano, Magma, Island arc, Horst, Geology, Seismology, Earth-Surface Processes
Abstract

The volcanic arc of the Hellenic subduction zone with its four volcanic centers is of major relevance when evaluating the seismovolcanic hazard for the Aegean region. We present results from a 22-station temporary seismic network (CYCNET) in the central Hellenic Volcanic Arc (HVA). CYCNET recordings allow to analyze the level and spatio-temporal evolution of microseismic activity in this region for the first time. A total of 2175 events recorded between September 2002 and July 2004 are analyzed using statistical methods, cluster analysis and relative relocation techniques. We identify distinct regions with significantly varying spatio-temporal behavior of microseismicity. A large portion of the seismic activity within the upper crust is associated with the presence of islands representing horst structures that were generated during the major Oligocene extensional phase. In contrast, the central part of the Cyclades metamorphic core complex remains aseismic considering our magnitude threshold of 1.8 except one spot where events occur swarm-like and with highly similar waveforms. The highest activity in the study area was identified along the SW–NE striking Santorini–Amorgos zone. Within this zone the submarine Columbo volcano exhibits strong temporal variations of seismic activity on a high background level. This activity is interpreted to be directly linked to the magma reservoir and therein the migration of magma and fluids towards the surface. NE of Columbo where no volcanic activity has yet been reported we observe a similar seismicity pattern with small-scaled activity spots that might represent local pathways of upward migrating fluids or even developing volcanic activity within this zone of crustal weakness. In contrast, the Santorini and Milos volcanic complexes do not show significant temporal variations and low to moderate background activity, respectively. Relating our results to the distribution of historical earthquakes and the GPS-derived horizontal velocity field we conclude that the Santorini–Amorgos zone is presently in the state of right-lateral transtension reflecting a major structural boundary of the volcanic arc subdividing it into a seismically and volcanically quiet western and an active eastern part.

Published
2006

9. Spatio-temporal microseismicity clustering in the Cretan region

Author

M. Rische, Thomas Meier, Hans-Peter Harjes, Marco Bohnhoff, and Dirk Becker

Subjects
Geophysics, Microseism, Subduction, Continental crust, Trench, Intraplate earthquake, 550 - Earth sciences, Crust, Earthquake swarm, Forearc, Geology, Seismology, Earth-Surface Processes
Abstract

Spatio-temporal clustering of microseismicity in the central forearc of the Hellenic Subduction Zone in the area of Crete is investigated. Data for this study were gathered by temporary short period networks which were installed on the islands of Crete and Gavdos between 1996 and 2004. The similarity of waveforms is quantified systematically to identify clusters of microseismicity. Waveform similarities are calculated using an adaptive time window containing both the P- and S-wave onsets. The cluster detection is performed by applying a single linkage approach. Clusters are found in the interplate seismicity as well as in the intraplate seismicity of the continental crust in the region of the transtensional Ptolemy structure. The majority of the clusters are off the southern coast of Crete, in a region of elevated intraplate microseismic activity within the Aegean plate. Clusters in the Gavdos region are located at depths compatible with the plate interface while cluster activity in the region of the Ptolemy trench is distributed along a nearly vertical structure throughout the crust extending down to the plate interface. Most clusters show swarm-like behaviour with seismic activity confined to only a few hours or days, without a dominant earthquake and with a power law distribution of the interevent times. For the largest cluster, precise relocations of the events using travel time differences of P- and S-waves derived from waveform cross correlations reveal migration of the hypocenters. This cluster is located in the region of the Ptolemy trench and migration occurs along the strike of the trench at ∼ 500 m/day. Relocated hypocenters as well as subtle differences in the waveforms suggest an offset between the hypocenters and thus the activation of distinct patches on the rupture surface. The observed microseismicity patterns may be related to fluids being transported along the plate interface and escaping towards the surface in zones of crustal weakness (Ptolemy structure), triggering swarm-like cluster activity along its way.

Published
2006

10. Seismicity of the Hellenic subduction zone in the area of western and central Crete observed by temporary local seismic networks

Author

Thomas Meier, B. Endrun, M. Rische, Hans-Peter Harjes, and Antonis Vafidis

Subjects
Hellenic arc, geography, geography.geographical_feature_category, Subduction, Hypocenter, Seismogenic zones, Induced seismicity, Temporary local seismic networks, Microseismicity, Geophysics, Receiver function, Ridge, Lithosphere, Intraplate earthquake, Aegean, Hellenic subduction zone, Seismology, Geology, Earth-Surface Processes
Abstract

Summarization: Temporary local seismic networks were installed in western Crete, in central Crete, and on the island Gavdos south of western Crete, respectively, in order to image shallow seismically active zones of the Hellenic subduction zone. More than 4000 events in the magnitude range between −0.5 and 4.8 were detected and localized. The resulting three-dimensional hypocenter distribution allows the localization of seismically active zones in the area of western and central Crete from the Mediterranean Ridge to the Cretan Sea. Furthermore, a three-dimensional structural model of the studied region was compiled based on results of wide-angle seismics, surface wave analysis and receiver function studies. The comparison of the hypocenter distribution and the structure has allowed intraplate and interplate seismicity to be distinguished. High interplate seismicity along the interface between the subducting African lithosphere and the Aegean lithosphere was found south of western Crete where the interface is located at about 20 to 40 km depth. An offset between the southern border of the Aegean lithosphere and the southern border of active interplate seismicity is observed. In the area of Crete, the offset varies laterally along the Hellenic arc between about 50 and 70 km. A southwards dipping zone of high seismicity within the Aegean lithosphere is found south of central Crete in the region of the Ptolemy trench. It reaches from the interface between the plates at about 30 km depth towards the surface. In comparison, the Aegean lithosphere south of western Crete is seismically much less active including the region of the Ionian trench. Intraplate seismicity within the Aegean plate beneath Crete and north of Crete is confined to the upper about 20 km. Between 20 and 40 km depth beneath Crete, the Aegean lithosphere appears to be seismically inactive. In western Crete, the southern and western borders of this aseismic zone correlate strongly with the coastline of Crete. Presented on: Tectonophysics

Published
2004

11. P and S velocity structures of the Santorini-Coloumbo volcanic system (Aegean Sea, Greece) obtained by non-linear inversion of travel times and its tectonic implications

Author

Panagiotis Hatzidimitriou, Thomas Meier, D. G. Panagiotopoulos, C. B. Papazachos, I. Dimitriadis, M. Rische, and Marco Bohnhoff

Subjects
geography, geography.geographical_feature_category, Volcanic arc, Seamount, Fracture zone, 550 - Earth sciences, Tectonics, Geophysics, Volcano, Geochemistry and Petrology, Seismic tomography, Low-velocity zone, Submarine volcano, Seismology, Geology
Abstract

One of the most prominent tectonic features of the Eastern Mediterranean region is the Hellenic volcanic arc in the Southern Aegean Sea, with the Santorini Island being one of the most active volcanic centers. Recent seismic studies show that the main seismic activity of the Santorini volcanic center is strongly associated with the volcanic processes, as well as with the seismo-tectonic regime of the broader Southern Aegean Sea area. The main cluster of local seismicity is located near the northeastern edge of the Santorini Island, beneath the Coloumbo Reef, which is a submarine volcanic seamount of the Santorini Island volcanic system. The P and S wave velocity structures of the Santorini–Coloumbo volcanic system is studied by inverting travel times of local earthquakes recorded by two independent dense seismic arrays installed in the broader area of Santorini islands during the period of September 2002–September 2005. In particular, 137 local earthquakes with 1600 P phases and 1521 S phases recorded by 25 seismological stations have been selected for the inversion. The inversion technique applied is non-linear, since three-dimensional ray tracing is incorporated. The reliability of the final tomographic results is demonstrated through resolutions tests using synthetic seismic data. The obtained results confirm the strong variations of the P and S wave velocity structures in the area of Santorini–Coloumbo volcanic system, as well as the connection between the tectonic setting of the study area with the magmatic processes taking place beneath the two volcanoes. The tomographic models show that a low-velocity zone extends along the northeastern edge of the Santorini Island, parallel to the “Kameni–Coloumbo” fracture zone (NE–SW direction), which corresponds to the western termination of the major ENE–WSW Santorini–Amorgos Fault Zone. Evidence is presented that this structural lineament corresponds to a tecto-volcanic fracture zone, which probably links the volcanic center of Santorini with the submarine volcano at Coloumbo Reef. Furthermore, the tomographic results show indications that the magmatic chamber beneath the Coloumbo volcanic seamount is located at a depth of 6–7 km in good agreement with recent independent studies in the area, though this feature is not within the resolving power of the employed data set.

Published
2010

12. CYC-NET: A temporary seismic network on the Cyclades (Aegean Sea, Greece)

Author

B. Endrun, G. Stavrakakis, M. Rische, Thomas Meier, Dirk Becker, Marco Bohnhoff, and Hans-Peter Harjes

Subjects
geography, geography.geographical_feature_category, Microseism, Volcanic arc, Subduction, Seismotectonics, CYCLADES, 550 - Earth sciences, Mantle (geology), Geophysics, Seismic hazard, Volcano, Seismology, Geology
Abstract

Densely spaced digital recording temporary seismic networks are a fundamental and widely used tool to monitor microseismic activity at a low detection threshold. Such networks provide data for various types of investigations, such as the evaluation of seismic hazard potential, structural analysis, and stress field determination. Here, we focus on monitoring in the south Aegean region, which has the highest seismic activity in Europe. In this region, such networks have been operated previously on the island of Crete ( e.g., Harjes et al., 1997; Delibasis et al., 1999; Becker, 2000; Jost et al. , 2002; Meier et al., 2003), in western Greece ( e.g., Leydecker et al., 1978; Hatzfeld et al., 1989; Sachpazi et al., 2000), and at the volcanic centers of Milos (Ochmann et al., 1989), Santorini (Panagiotopoulos et al., 1996), and Nisyros (Makris and Chonia, 1999). Furthermore, Hatzfeld et al. (1993a, 1993b) analyzed a seismic network covering the whole Aegean region. The present knowledge of seismotectonics of the volcanic arc of the Hellenic subduction zone poses a number of questions that can best be addressed via an investigation of the spatiotemporal distribution of hypocenters. The principal open questions in the area of investigation are: How is the shallow and intermediate-depth seismic activity distributed in the central Hellenic volcanic arc? What is the interaction between spatiotemporal evolution of hypocenters and upward-migrating fluids and magma? Why is the seismicity clustered in space and time over a broad range of magnitudes? What is the crustal and uppermost mantle structure along the central volcanic arc? To address these questions, it is desirable to obtain hypocenters with small location errors and at a low detection threshold. In this paper we describe a seismic network that was installed in Autumn 2002 on the Cyclades island group that covers the …

Published
2004

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