197 research outputs found
FrequencyâDependent Moment Tensors of Induced Microearthquakes
Analysis of 984 induced microearthquakes from The Geysers geothermal reservoir in California reveals that the retrieved moment tensors depend on the frequency band of the inverted waveforms. The observed dependence is more significant for the percentages of the doubleâcouple, compensated linear vector dipole, and isotropic (ISO) components than for the focal mechanisms. The average rootâmeanâsquare of the moment tensors obtained in different frequency bands is correlated with spectra of ambient noise. The percentages of doubleâcouple and ISO components tend to decrease and increase with the upper cutoff frequency (fu), respectively. This suggests that shear rupture radiates energy preferentially in a lower frequency band and tensile rupture in a higher frequency band. Events displaying a strong increase of the ISO with fu are confined within the same depth interval as the injection points. This might be related to the strong thermoelastic effects in the vicinity of injection points that promote opening of small cracks adjacent to the main fractures
Seismotectonic setting at the North Anatolian Fault Zone after the 1999 Mw=7.4 Izmit earthquake based on high-resolution aftershock locations
International audienceThe most recent devastating earthquakes that occurred along the North Anatolian Fault Zone (NAFZ) in northwestern Turkey were the 1999 Izmit (Mw=7.4) and DĂŒzce (Mw=7.1) events. In this study we present a catalog of Izmit aftershock hypocenters that was deduced from a network covering the entire 140 km long rupture of the mainshock. 7348 events with a location accuracy better than 5 km are analysed. Aftershocks were observed along the entire ruptured segment along a 20 km wide band of activity. Events are clustered in distinct regions and dominantly occur at 5 to 15 km depth. The eastern termination of the Izmit rupture is characterized by a sharp and steeply dipping boundary exactly where the DĂŒzce mainshock initiated 87 days after the Izmit event. Relocation of the events using double-difference technology results in 4696 high-resolution hypocenters that allow resolving the internal structure of the seismically active areas with a resolution of 300 m (horizontal) and 400m (vertical). Below the Akyazi Plain, representing a small pull-apart structure at a triple junction of the NAFZ, we identify planes of activity that can be correlated with nodal planes of EW extensional normal faulting aftershocks. Along the easternmost Karadere-DĂŒzce segment we identify the down-dip extension of the Karadere fault that hosted about 1 m of right-lateral coseismic slip. At the easternmost rupture we correlate a cloud-type distribution of seismic activity with the largest aftershocks in this area, a subevent of the Izmit mainshock and the DĂŒzce mainshock that all have an almost identical focal mechanism. This part of the NAFZ is interpreted as a classical example of a seismic barrier along the fault
Metre-scale damage zone characterization using S-coda waves from active ultrasonic transmission measurements in the STIMTEC project, URL Reiche Zeche, Germany
Studies of controlled hydraulic stimulation experiments with active and passive seismic monitoring conducted in Underground Research Laboratories (URLs) benefit from specific knowledge of hydraulic parameters, close by microseismic monitoring revealing structural details of the rock mass, and detailed evolution of seismicity in response to injection operations. Microseismic monitoring is commonly used to characterize a stimulated reservoir volume, for example, in terms of damage evolution of the rock mass. Since seismic attenuation is affected by damage of the rock volume, active seismic sources covering sizes from the centimetre to decimetre scale may help us to investigate spaceâtime varying attenuation properties in a reservoir. This may allow us to monitor damage evolution of the stimulated rock volume in more detail, also since active seismic sources produce stronger signals leading to a broader frequency range that can be analysed compared to passive seismic signals. Within the STIMTEC project in the URL Reiche Zeche (URL-RZ) in Freiberg (Germany), more than 300 active Ultrasonic Transmission (UT) measurements were performed before and after hydraulic stimulations in two boreholes in the targeted rock volume, an anisotropic metamorphic gneiss. The signal-frequency content ranges between 1 and 60 kHz. Assuming scattering attenuation to dominate over intrinsic attenuation, we here apply the single isotropic scattering model. S-coda waves of 88 spatially representative UT measurements are used to estimate the coda quality factor (QC). We obtain stable QC estimates for centre frequencies of octave-width frequency bands between 3 and 21 kHz. We group neighbouring UT measurements to stabilize the observations and form eight UT groups in total, covering different depth intervals in three boreholes and four different time periods to investigate scattering attenuation changes in a spatiotemporal manner. Our final mean QC (â QCÂŻÂŻÂŻÂŻÂŻÂŻÂŻâ ) estimates show characteristic frequency-dependence as observed at the field scale in geological reservoirs. We find temporal variations of QC are strongly connected to hydraulic stimulation, and these variations are more significant than those resolved from velocity changes. QCÂŻÂŻÂŻÂŻÂŻÂŻÂŻ estimates at frequencies above 15 kHz indicate healing of injection-induced small-scale fractures during a two-months post-stimulation phase. Larger fractures, mostly sampled by lower frequencies (<15 kHz), seem to be more persistent with time (over 15 months). We observe spatial differences of QCÂŻÂŻÂŻÂŻÂŻÂŻÂŻ values near the mine galleries (driftway and vein drift) and relate these observations to different extents and characteristics of the galleriesâ excavation damage zones. Our results further support previous assumptions based on borehole televiewer logs and mapped structures of an existing fault with larger damage zone that crosses the stimulated rock volume NW-SE between the galleries. We conclude that the coda analysis of active UT measurements complements established imaging methods used during experiments in URLs. In particular, coda analysis is a powerful tool for the detection of damage zones and for monitoring local fracture networks with immediate application for imaging georeservoirs considered for exploitation or underground storage of gases and liquids
Crustal Thickness Variation Across the Sea of Marmara Region, NW Turkey: A Reflection of Modern and Ancient Tectonic Processes
The Marmara region in Turkey is an important geological setting, both from a tectonic and a seismic hazard/risk perspective. We present a new map of crustal thickness variation across this complex region to better understand the interplay of past and present tectonic processes that have formed presentâday structure. Maps of crustal thickness are created using Ps converted phases and receiver function (RF) analysis of earthquakes recorded at all publicly available seismic stations and stations in the national monitoring network (run by AFAD Disaster and Emergency Management Authority Turkey). RFs are converted from time to depth using a local 3âD fullâwaveform tomographic model and are combined in multiphase common conversion point stacks. Direct P to S converted arrivals and associated multiples are mapped to produce continuous maps of the Moho discontinuity. Results show Moho depths ranging from 26â41 km with a regional trend of westward thinning reflecting the effects of the extensional regime in western Anatolia and the neighboring Aegean Sea. The thinnest crust is observed beneath the western end of the Sea of Marmara, attributed to transtensional basin opening. A distinct region of increased crustal thickness bounded by the West Black Sea Fault in the west, and the northern strand of the North Anatolian Fault in the south, defines the ancient crustal terrane of the Istanbul Zone. Isostatic arguments indicate that the thickened crust and lower elevation in the Istanbul Zone require it to be underlain by thicker lithosphere, a conclusion that is consistent with its hypothesized origin near the Odessa shelf
Sea Level Changes Affect Seismicity Rates in a Hydrothermal System Near Istanbul
Small stress changes such as those from sea level fluctuations can be large enough to trigger earthquakes. If small and large earthquakes initiate similarly, high-resolution catalogs with low detection thresholds are best suited to illuminate such processes. Below the Sea of Marmara section of the North Anatolian Fault, a segment of urn:x-wiley:00948276:media:grl65397:grl65397-math-0001150 km is late in its seismic cycle. We generated high-resolution seismicity catalogs for a hydrothermal region in the eastern Sea of Marmara employing AI-based and template matching techniques to investigate the link between sea level fluctuations and seismicity over 6 months. All high resolution catalogs show that local seismicity rates are larger during time periods shortly after local minima of sea level, when it is already rising. Local strainmeters indicate that seismicity is promoted when the ratio of differential to areal strain is the largest. The strain changes from sea level variations, on the order of 30â300 nstrain, are sufficient to promote seismicity
Direct Evidence of a SlowâSlip Transient Modulating the Spatiotemporal and FrequencyâMagnitude Earthquake Distribution: Insights From the Armutlu Peninsula, Northwestern Turkey
Earthquakes and slowâslip events interact, however, detailed studies investigating their interplay are still limited. We generate the highest resolution microseismicity catalog to date for the northern Armutlu Peninsula in a âŒ1âyear period to perform a detailed seismicity distribution analysis and correlate the results with a local, geodetically observed slowâslip transient within the same period. Seismicity shows a transition of clusterâtype behavior from swarmâlike to burstâlike, accompanied by an increasing relative proportion of clustered (nonâPoissonian) relative to background (Poissonian) seismicity and gradually decreasing bâvalue as the geodetically observed slowâslip transient ends. The observed slowâslip transient decay correlates with gradually increasing effectiveâstressâdrop values. The observed correlation between the bâvalue and geodetic transient highlights the influence of aseismic deformation on seismic deformation and the impact of slowâslip transients on local seismic hazard
ML scale in Northwestern Turkey from 1999 Izmit aftershock: updates
Abstract We present an update of the local magnitude scale previously calibrated
for northwestern Turkey by Baumbach et al. (2003). The path coverage in the westernmost
part of the analyzed area has been increased, as well as the number of
amplitudes for distance greater than 110 km. Furthermore, a set of recordings from
accelerometric stations operated by the Kandilli Observatory and Earthquake Research
Institute (KOERI) has been merged with the recordings by the Sapanca-Bolu
and German Task Force seismological networks. In all, 4047 recordings from
528 earthquakes recorded by 31 seismometers and 23 accelerometers are considered
to calibrate the local magnitude scale over a hypocentral distance range from 10
to 190 km. By analyzing the unit covariance matrix and the resolution matrix, we
show how the source-to-station geometries of the seismic and strong-motion networks
affect the uncertainties of the computed station corrections, attenuation coefficients,
and magnitudes. The assumptions made concerning the reference station
correction, and the change in the amplification for the WoodâAnderson torsion seismograph
from 2800 to 2080 (Uhrhammer and Collins, 1990) introduced an offset of
about 0.34 in the magnitudes with respect to Baumbach et al. (2003), with the updated
local magnitude scale ranges from 0.50 to 5.91. The distribution of the residuals with
distance confirms that the extension of both the magnitude and distance ranges and
the improved path coverage have preserved the high quality that characterized the
data set analyzed by Baumbach et al. (2003)
ML scale in Northwestern Turkey from 1999 Izmit aftershocks: updates
We present an update of the local magnitude scale previously calibrated for Northwestern Turkey
by Baumbach et al. (2003). The path coverage in the westernmost part of the analysed area has been
increased, as well as the number of amplitudes for distance greater than 110 km. Furthermore, a set
of recordings from accelerometric stations operated by the Kandilli Observatory and Earthquake
Research Institute (KOERI) has been merged with the recordings by the Sapanca-Bolu and
GermanTaskForce seismological networks. In all, 4047 recordings from 528 earthquakes recorded
by 31 seismometers and 23 accelerometers are considered to calibrate the local magnitude scale
over a hypocentral distance range from 10 to 190 km. By analyzing the unit covariance matrix and
the resolution matrix, we show how the source-to-station geometries of the seismic and strong
motion networks affect the uncertainties of the computed station corrections, attenuation
coefficients, and magnitudes. The assumptions made concerning the reference station correction,
and the change in the amplification for the Wood-Anderson torsion seismograph from 2800 to 2080
(Uhrhammer and Collins, 1990) introduced an offset of about 0.34 in the magnitudes with respect to
Baumbach et al. (2003), with the updated local magnitude scale ranges from 0.50 to 5.91. The
distribution of the residuals with distance confirms that the extension of both the magnitude and
distance ranges and the improved path coverage have preserved the high quality that characterized
the data set analyzed by Baumbach et al. (2003)
Gas and seismicity within the Istanbul seismic gap
Understanding micro-seismicity is a critical question for earthquake hazard
assessment. Since the devastating earthquakes of Izmit and Duzce in 1999, the
seismicity along the submerged section of North Anatolian Fault within the Sea
of Marmara (comprising the âIstanbul seismic gapâ) has been extensively
studied in order to infer its mechanical behaviour (creeping vs locked). So
far, the seismicity has been interpreted only in terms of being tectonic-
driven, although the Main Marmara Fault (MMF) is known to strike across
multiple hydrocarbon gas sources. Here, we show that a large number of the
aftershocks that followed the M 5.1 earthquake of July, 25th 2011 in the
western Sea of Marmara, occurred within a zone of gas overpressuring in the
1.5â5âkm depth range, from where pressurized gas is expected to migrate along
the MMF, up to the surface sediment layers. Hence, gas-related processes
should also be considered for a complete interpretation of the micro-
seismicity (~Mâ<â3) within the Istanbul offshore domain
Gas and seismicity within the Istanbul seismic gap
Understanding micro-seismicity is a critical question for earthquake hazard assessment. Since the devastating earthquakes of Izmit and Duzce in 1999, the seismicity along the submerged section of North Anatolian Fault within the Sea of Marmara (comprising the âIstanbul seismic gapâ) has been extensively studied in order to infer its mechanical behaviour (creeping vs locked). So far, the seismicity has been interpreted only in terms of being tectonic-driven, although the Main Marmara Fault (MMF) is known to strike across multiple hydrocarbon gas sources. Here, we show that a large number of the aftershocks that followed the M 5.1 earthquake of July, 25th 2011 in the western Sea of Marmara, occurred within a zone of gas overpressuring in the 1.5â5âkm depth range, from where pressurized gas is expected to migrate along the MMF, up to the surface sediment layers. Hence, gas-related processes should also be considered for a complete interpretation of the micro-seismicity (~Mâ<â3) within the Istanbul offshore domain
- âŠ