Optimized Seismic Threshold Monitoring – Part 2: Teleseismic Processing

v--vThis second paper (Part 2) pertaining to optimized site-specific threshold monitoring addresses the application of the method to regions covered by a teleseismic or a combined regional-teleseismic network. In the first paper (Part 1) we developed the method for the general case, and demonstrated its application to an area well-covered by a regional network (the Novaya Zemlya nuclear test site). In the present paper, we apply the method to the Indian and Pakistani nuclear test sites, and show results during the periods of nuclear testing by these two countries in May 1998. Since the coverage by regional stations in these areas is poor, an optimized approach requires the use of selected, high-quality stations at teleseismic distances.¶To optimize the threshold monitoring of these test sites, we use as calibration events either one of the nuclear explosions or a nearby earthquake. From analysis of the calibration events we derive values for array beamforming steering delays, filter bands, short-term averages (STA) lengths, phase travel times (P waves), and amplitude-magnitude relationships for each station. By applying these parameters, we obtain a monitoring capability of both test sites ranging from m_b 2.8-3.0 using teleseismic stations only. When including the nearby Nilore station to monitor the Indian tests, we show that the threshold can be reduced by about 0.4 magnitude units. In particular, we demonstrate that the Indian tests on 13 May, 1998, which were not detected by any known seismic station, must have corresponded to a magnitude (m_b) of less than 2.4.¶We also discuss the effect of a nearby aftershock sequence on the monitoring capability for the Pakistani test sites. Such an aftershock sequence occurred in fact on the day of the last Pakistani test (30 May, 1998), following a large (m_b 5.5) earthquake in Afghanistan located about 1100 km from the test site. We show that the threshold monitoring technique has sufficient resolution to suppress the signals from these interfering aftershocks without significantly affecting the true peak of the nuclear explosion on the threshold trace.     

Blockage of regional seismic waves by the Teisseyre-Tornquist zone

During the Group of Scientific Experts Technical Test (GSETT, second experiment, 22 April-2 June 1991), several hundred seismic events were located in Europe. Associating these events with the detecting stations-altogether 28 European stations including seven arrays participated in the GSETT-2 experiment-clearly shows that the Teisseyre-Tornquist Zone (TTZ) influences the propagation of regional seismic phases. Large explosions in the Bay of Gdańsk, for example, were observed by the well-established Scandinavian arrays'NORSAR (Δ 830km) and ARCESS (Δ 1650km), but not by the Polish station KSP (Δ 470km) nor by the new highly sensitive GERESS array (Δ 750km), both situated south-west of the TTZ. For events in central Europe with comparable magnitudes, we observe a similar increase of the detection threshold at stations located north-east of the TTZ in Scandinavia. to explain these observations, the wave propagation of P_n and P_g perpendicular to the TTZ was modelled for a profile from the Estonian/Russian border region to GERESS with Gaussian-beam seismograms. Published crustal and uppermost mantle models for Poland and for Europe were used as a starting point for developing a model of the TTZ. the observations cannot be explained only by a graben-like crustal structure with a jump in Moho depth from 30km to 50km. to defocus the seismic energy, the TTZ as a structural anomaly between eastern and western Europe must reach down into the upper mantle to a depth of at least about 200 km. the proposed model has such a deep-reaching root of the TTZ.     

Parametric cubic splines and geologic shape descriptions

Parametric cubic splines provide a versatile means of describing and sampling shapes and curves commonly found in geology. These splines allow the researcher to treat easily curves which are not single-valued in Cartesian or polar coordinates. In addition, they simultaneously provide approximations to positions, slopes, and curvatures of the curve being considered. In conjunction with simple digitizing equipment and a small computer, the method of parametric cubic spline approximation allows the researcher to analyze curves or outlines in cases where the more rapid technique involving video imaging equipment is either not applicable or not available.     

Korrelation der Sporenzonen der Oberen Trias und des Jura im Mittleren Orient und in Süddeutschland

Zusammenfassung Bei der sporenstratigraphischen Gliederung des mittleren Mesozoikums im Mittleren Orient konnten vom Nor bis zur Unteren Kreide 6 Sporenzonen unterschieden werden: Unterkreide:Ischyosporites variegatus — Rouseisporites laciniatus — Cicatricosisporites-Zone Malm:Ischyosporites variegatus — Rouseisporites laciniatus-Zone Dogger:Ischyosporites variegatus — Duplexisporites problematicus-Zone Lias:Concavisporites — Duplexisporites problematicus-Zone Rät:Concavisporites — Duplexisporites problematicus — Lophotriletes sangburensis — Ricciisporites tuberculatus-Zone Nor:Concavisporites — Duplexisporites problematicus — Lophotriletes sangburensis — Cyclotriletes oligogranifer-ZoneVergleichende Untersuchungen ergaben, daß diese Sporenzonen auch auf Süddeutschland übertragbar sind und den faunistischen Grenzen entsprechen. Nur die sporenstratigraphische Festlegung der Nor/Rätsowie der Dogger/Malm- und der Malm/Unterkreide-Grenze bedürfen noch der Verifizierung.

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In the middle Mesozoic of the Middle East 6 spore-assoziations could be distinguished from the Norian to the Lower Cretaceous: Lower Cretaceous:Ischyosporites variegatus — Rouseisporites laciniatus — Cicatricosisporites zone Upper Jurassic:Ischyosporites variegatus — Rouseisporites laciniatus zone Middle Jurassic:Ischyosporites variegatus — Duplexisporites problematicus zone Lower Jurassic:Concavisporites — Duplexisporites problematicus zone Rhaetian:Concavisporites — Duplexisporites problematicus — Lophotriletes sangburensis — Ricciisporites tuberculatus zone Norian:Concavisporites — Duplexisporites problematicus — Lophotriletes sangburensis — Cyclotriletes oligogranifer zone.The interregional validity and the correspondance of these spore zones with the faunistic boundaries could be substantiated in equivalent sequences in Southern Germany. However, the palynological definition of the Norian/Rhaetian, Middle/Upper Jurassic and Jurassic/Cretaceous boundaries have still to be confirmed in other regions since suitable sections have not been available in Southern Germany.

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Résumé Dans le Mésozoïque moyen du Moyen Orient, six zones de spores peuvent être distinguées du Norien au Crétacé inférieur: Crétacé inférieur: Zone àIschyosporites variegatus — Rouseisporites laciniatus — Cicatricosisporites Jurassique supérieur: Zone àIschyosporites variegatus — Rouseisporites laciniatus Jurassique moyen: Zone àIschyosporites variegatus — Duplexisporites problematicus Jurassique inférieur: Zone àConcavisporites — Duplexisporites problematicus Réthien: Zone àConcavisporites — Duplexisporites problematicus — Lophotriletes sangburensis — Ricciisporites tuberculatus Norien: Zone àConcavisporites — Duplexisporites problematicus — Lophotriletes sangburensis — Cyclotriletes oligogranifer Une étude comparative montre que les mêmes zones de spores existent en Allemagne du sud et qu'elles correspondent aux limites faunistiques. Toutefois, les limites Norien/ Rhétien, Dogger/Malm et Malm/Crétacé inférieur demandent à être vérifiées.

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- : : Ischyosporites variegatus —Rouseisporites laciniatus — Cicatricosisporites : Ischyosporites variegatus — Rouseisporites laciniatus : Ischyosporites variegatus — Duplexisporites problematicus : Concavisporites — Duplexisporites problematicus : Concavisporites — Duplexisporites problematicus — Lophotriletes sangburensis — Ricciisporites tuberculatus : Concavisporites — Duplexisporites problematicus — Lophotriletes sangburensis — Cyclotriletes oligogranifer. , , . , /, / / .

     

Observations of tectonic microdisplacements in Europe in relation to the Iran 1997 and Turkey 1999 earthquakes

Long-term repeated measurements of microdisplacements in tectonic fault structures of various parts of Central Europe and the Balkan Mountains showed that displacement trends changed significantly at several points in the period from 1997 through 2000; afterward, long-term trends were restored. This phenomenon took place in the periods of strong (M > 7) earthquakes in Iran (1997) and in the North Anatolian fault zone in Turkey (1999). Two strong Izmit earthquakes of 1999 in Turkey at distances of 600 km from the Balkan Peninsula and 1400 km from observation points in Central Europe were the main seismic events of the period studied. Apparently, the crustal deformation due to the sources of the aforementioned earthquakes reaches the central part of the European craton. Anomalous displacements in some areas occurred due to deformation propagating for great distances in the heterogeneous block medium of the West European part of the Eurasian plate. Changes in stresses can be caused by impulsive deformations of various intensities acting on some structural units (fault segments) at various distances.     

BARENTS16: a 1-D velocity model for the western Barents Sea

A minimum 1-D seismic velocity model for routine seismic event location purposes was determined for the area of the western Barents Sea, using a modified version of the VELEST code. The resulting model, BARENTS16, and corresponding station corrections were produced using data from stations at regional distances, the vast majority located in the periphery of the recorded seismic activity, due to the unfavorable land–sea distribution. Recorded seismicity is approached through the listings of a joint bulletin, resulting from the merging of several international and regional bulletins for the region, as well as additional parametric data from temporary deployments. We discuss the challenges posed by this extreme network-seismicity geometry in terms of velocity estimation resolution and result stability. Although the conditions do not facilitate the estimation of meaningful station corrections at the farthermost stations, and even well-resolved corrections do not have a convincing contribution, we show that the process can still converge to a stable velocity average for the crust and upper mantle, in good agreement with a priori information about the regional structure and geology, which reduces adequately errors in event location estimates.     

Application of array-based waveform cross-correlation techniques to aftershock sequences: the 2003 Lefkada Island,Greece, case

Cross-correlation analysis was applied to events in the 2003 Lefkada Island, Greece, sequence in order to identify clusters of seismicity within the extensive aftershock sequence along a fault zone of approximately 100 km length. Data from the small-aperture TRISAR array, covering the first 2 days of aftershock activity, were used. Array-based waveform correlation has a great advantage over single channel correlation analysis in that the validity of waveform matches with relatively low correlation coefficients can be examined by checking the alignment of correlation traces on the different channels. The length of the fault zone leads inevitably to a great diversity in the waveforms, although a small number of clusters of very similar events emerge from the TRISAR data. Events which the correlation analysis had placed within the same cluster were listed in the ISC Bulletin with separations of up to tens of kilometres. This made it necessary to check the validity of the TRISAR clusters by applying the same procedure independently to the three-component stations of the National Seismographic Network of the National Observatory of Athens, located at local to regional distances from the aftershock area. Results suggest that array-based waveform correlation provides a robust tool both for identifying event clusters within large aftershock areas and for identifying situations in which bulletin event location estimates need re-evaluation.