Your search keyword '"Bulut, Nevra"' showing total 8 results

1. Finite-Frequency Body-Wave Tomography in Scandinavia

Author

Bulut, Nevra, primary and Thybo, Hans, additional

Published

2022

2. ScanArray : A Broadband Seismological Experiment in the Baltic Shield

Author

Thybo, Hans, Bulut, Nevra, Grund, Michael, Mauerberger, Alexandra, Makushkina, Anna, Artemieva, Irina M., Balling, Niels, Gudmundsson, Ólafur, Maupin, Valerie, Ottemøller, Lars, Ritter, Joachim, Tilmann, Frederik, Thybo, Hans, Bulut, Nevra, Grund, Michael, Mauerberger, Alexandra, Makushkina, Anna, Artemieva, Irina M., Balling, Niels, Gudmundsson, Ólafur, Maupin, Valerie, Ottemøller, Lars, Ritter, Joachim, and Tilmann, Frederik

Abstract

The ScanArray international collaborative program acquired broadband seismological data at 192 locations in the Baltic Shield during the period between 2012 and 2017. The main objective of the program is to provide seismological constraints on the structure of the lithospheric crust and mantle as well as the sublithospheric upper mantle. The new information will be applied to studies of how the lithospheric and deep structure affect observed fast topographic change and geological‐tectonic evolution of the region. The program also provides new information on local seismicity, focal mechanisms, and seismic noise. The recordings are generally of very high quality and are used for analysis by various seismological methods, including P‐ and S‐wave receiver functions for the crust and upper mantle, surface wave and ambient noise inversion for seismic velocity, body‐wave P‐ and S‐wave tomography for upper mantle velocity structure using ray and finite frequency methods, and shear‐wave splitting measurements for obtaining bulk anisotropy of the upper and lowermost mantle. Here, we provide a short overview of the data acquisition and initial analysis of the new data, together with an example of integrated seismological results obtained by the project group along a representative ∼1800‐km‐long profile across most of the tectonic provinces in the Baltic Shield between Denmark and the North Cape. The first models support a subdivision of the Paleoproterozoic Svecofennian province into three domains, where the highest topography of the Scandes mountain range in Norway along the Atlantic Coast has developed solely in the southern and northern domains, whereas the topography is more subdued in the central domain.

Published

2021

3. ScanArray—A Broadband Seismological Experiment in the Baltic Shield

Author

Thybo, Hans, primary, Bulut, Nevra, additional, Grund, Michael, additional, Mauerberger, Alexandra, additional, Makushkina, Anna, additional, Artemieva, Irina M., additional, Balling, Niels, additional, Gudmundsson, Olafur, additional, Maupin, Valerie, additional, Ottemøller, Lars, additional, Ritter, Joachim, additional, and Tilmann, Frederik, additional

Published

2021

4. ScanArray - Seismological study of the connection between topographic change and deep structure in Fennoscandia

Author

Thybo, Hans, primary, Bulut, Nevra, additional, Grund, Michael, additional, Mauerberger, Alexandra, additional, Makushkina, Anna, additional, Artemieva, Irina, additional, Balling, Niels, additional, Gudmundsson, Olafur, additional, Maupin, Valerie, additional, Ottemøller, Lars, additional, Ritter, Joachim, additional, and Tilmann, Frederik, additional

Published

2021

5. Seismic Body-Wave Tomography in Fennoscandia

Author

Bulut, Nevra, primary, Maupin, Valerie, additional, and Thybo, Hans, additional

Published

2021

6. Seismic P- and S-wave velocity Tomography in Scandinavia

Author

Bulut, Nevra, primary, Maupin, Valerie, additional, and Thybo, Hans, additional

Published

2020

7. Adana havzası sismik gürültü kaynaklarının konum ve zaman özelliklerinin belirlenmesi

Author

Bulut, Nevra, Kaşlılar Şişman, Ayşe, and Jeofizik Mühendisliği Ana Bilim Dalı

Subjects

Geophysics Engineering, Jeofizik Mühendisliği

Abstract

Artalan Sismik Gürültüler (ASG), yerkürenin, gerek kendi içindeki hareketlenmeleri gerekse de dış etkenlerle etkileşimi sonucunda sismik enerjinin açığa çıkmasıyla oluşan farklı periyot bantlarına sahip cisim ve yüzey dalgalarıdır. Daha önceleri veriyi kirlettiği gerekçesiyle istenmeyen ve süzgeçlenerek bastırılmaya çalışılan gürültü sinyalleri son yıllarda geliştirilen yöntemlerin de katkısıyla, yüzey dalgalarından Green fonksiyonu eldesi ile kabuk ve manto hız yapısının araştırılması, petrol aramaları, zemin araştırmaları gibi pek çok çalışmada veri olarak kullanılmaktadır. Aynı zamanda gürültünün nitelendirilmesi dünyada binlercesi kurulu olan sismografların performansını daha iyi anlamaya ve veri kalitesini artırmaya yardımcı olacaktır. Bu tez çalışmasının amacı, nüfusu yüksek, endüstriyel anlamda gelişmiş ve tektonik olarak aktif bir coğrafyada bulunan sedimanter Adana Havzası ve çevresinin sismik gürültü niteliğinin zamana, konuma, jeolojiye ve kültürel yapılarak bağlı olarak araştırılması ve değerlendirilmesidir. Çalışmada kullanılan 2011 ve 2012 yıllarına ait sürekli sismik kayıtlar, Boğaziçi Üniversitesi Kandilli Rasathanesi Deprem Araştırma Enstitüsü (KRDAE) ve T.C Başbakanlık Afet ve Acil Durum Yönetimi Başkanlığı Deprem Dairesi Başkanlığı (AFAD-DAD)' na ait, Adana Havzası' nda bulunan 17 adet geniş bantlı Güralp CMG-3T ve Güralp CMG-3ESP marka hız kayıtçıları ile toplanmıştır. Havzanın sismik gürültü değerlendirmesine geçmeden önce yöntem ayrıntılarının verilmesinin yanı sıra programı ve kullanılacak verileri tanımaya yönelik bir takım çalışmalarda bulunulmuştur. Uygulanan gürültü analizi yönteminde, düşey bileşenli verilerin güç yoğunluğu spektrumları (GYS), olasılık yoğunluk fonksiyonları (OYF) ve spektrogramları açık kaynaklı PQLX (Passcal Quick Look eXtented) programı kullanılarak hesaplatılmış ve çizdirilmiştir. Havzadaki gürültü dağılımının zamana ve konuma bağlı değişiminin incelenmesi için GMT programı kullanılarak hazırlanan haritalarda, kültürel gürültülerin yani mikrotremörlerin (kaynak: trafik, insan, makine vb.) baskın olarak gözlendiği 0.1-1 s bandı ve mikrosalınım olarak da bilinen mikroseizmların (kaynak: derin ve sığ su etkileşimleri) gözlendiği 4-8 s (İkincil Yüksek Frekans veya Double Frequency Peak) ve 10-20 s (Birincil Yüksek Frekans veya Single Frequency Peak) bantlarındaki gürültü verileri, 2011 yılı, yaz-kış mevsimleri ve gece-güz saatleri için haritalanmıştır. Öte yandan kıyıya yakın bir istasyon ile karasal ortama kurulmuş ve aynı jeolojik formasyon üzerindeki istasyon arasındaki farklar spektrogramları hesaplanarak incelenmiştir. Bölgede üç bileşen xviii kaydı mevcut olan KRDAE verileri kullanılarak gürültülerin mod değerlerinin yatay ve düşey bileşenlerdeki durumu incelenmiş ve gözlenen farklar tartışılmıştır. Elde edilen sonuçlara göre gün içindeki gürültü seviyesi değişimlerinin yüksek frekanslı kültürel gürültülerden kaynaklandığı gözlenmiştir. Mevsimler arasındaki değişimler ise ancak uzun periyotlarda gözlenebilmiştir. Genel olarak, kültürel gürültüler yerleşimin ve sediman kalınlığının fazla olduğu havza içinde her zaman yüksek değerlerde gözlenirken, uzun periyotlu mikrotitreşimlerin daha çok havza sınırlarını etkilediği söylenebilir. Çalışmada 2011 yılı düşey bileşen kayıtlar için periyoda bağlı elde edilen en yüksek ve en düşük mod değerleri grafiklenerek bölgeye ait yüksek ve düşük gürültü modeli oluşturulmuştur. Bu çalışma ile bölgedeki istasyonların ve toplanan verinin kalitesi hakkında bilgi sağlanmıştır. Özellikle bazı istasyonlarda veri kayıtlarının sürekli olmadığı veya alet kökenli arızalar nedeniyle veri kalitesinin bozulduğu gözlenmiştir. Kullanılan yöntem, kurulu istasyonların sürekli izlenmesi ve arızaların öngörülüp zamanında müdahale edilmesine ve dolayısı ile veri kaydı sürekliliğine katkı sağlayabilir. Çalışmada elde edilen en yüksek ve en düşük gürültü modeli ve gürültü haritaları, bundan sonra bölgeye yerleştirilecek güncel istasyonlar için referans model olarak kullanılabilir. Gürültü seviyesi düşük bölgeler daha düşük manyitüdlü depremlerin kayıtlarına olanak sağlayabilirken, yüksek gürültülü bölgelerde manyitüdü daha büyük depremler kayıt edilebilecektir. Bu çalışmada elde edilen bilgiler yine gürültü verilerinin kullanılacağı dizilim işleme, yatay/düşey spektral oranlama, artalan sismik gürültü tomografisi, zemin özelliklerini ve sediman kalınlığını belirlemeye yönelik gürültü kökenli birçok çalışmada referans olarak kullanılabilir. The ambient seismic noise is widely used in imaging the subsurface structure. One of the popular applications is the retrieval of surface waves Green's functions that are used to obtain the velocity distributon in the Earth's crust and mantle. Ambient noise is also used in oil exploration and in near-surface studies for soil characterizations. In such studies the characterization of the noise can help to better understand the performance of each seismograph and the noise levels at each station which can contribute to interpretations of the results obtained by other ambient noise studies. In this study the characteristics of background seismic noise levels in the Adana Basin and its surroundings (Southern Turkey) are investigated. The Adana Basin is an inter-mountain, NE-SW trending basin. The depositional history, geological formations and thickness of the sediments suggest high potential for hydrocarbon settings. Besides, it is a developing region both in population and industry, a tectonically active area and hence prone to seismic hazards. Several studies are performed or under progress to understand the subsurface structure of the region. The characterization of the quality of noise data and the ambient seismic noise levels of the region may contribute to the ongoing and future studies, such as tomography, array processing and H/V spectral ratio studies, based on ambient noise. For this purpose the continuous noise data is processed recorded in 2011 by the noise analysis method given in Chapter 2. Adana Basin and its surroundings, is an arcuate, open V shape structure extending in NE-SW direction in the northeastern Mediterranean Sea. The basin is developed on Tauride basement rocks mainly in Neogene times, affected by the interplay of the African plate with the Arabian and Anatolian microplates. The basin is primarily controlled by NE-SW trending faults that are splays of the larger sinistral East Anatolian Fault. Three main rivers occupy the Adana Basin and form a major deltaic complex in the region. The previous studies suggest a sediment thickness between 3 km to 6 km. The aim of this study is to characterize the seismic noise and the quality of the continuous noise data in the region which will contribute to the recent and future seismic studies. For this reason, the vertical component continuous data recorded during 2011 by seventeen broadband Guralp CMG-3T, Güralp CMG-3T and Güralp CMG-3ESP velocity sensors with sampling rates 50 and 100 sps are used. The national seismic networks in the investigated sites are operated by KOERI (Kandilli Observatory and Earthquake Research Institute) and ERD (Earthquake Research Department of Disaster and Emergency Management Presidency of Turkey). xx In a continuous seismic record, besides noise, earthquakes, system transients and instrumental glitches (data gaps, clipping, spikes, mass recenters, calibration pulses) will be present. For the characterization of the noise, removal of this kind of distortions is necessary. In the method mentioned in Chapter 2 the discrimination of these distortions are provided by the calculation of the probability density functions (PDFs) of the seismic data. As the distortions are represented by low probabilities, the power values with high probabilities correspond to stationary background noise at each station. Details of system transients and instrument glitches are given in Chapter 3 with some demonstrations of seismic traces and PSD curves. In Chapter 4, investigation of spatial and temporal noise properties in the Adana Basin and its surroundings are studied. At last, final comments and results are discussed (Chapter 5). In this study the open source software Passcal-Iris Quick Look eXtented (PQLX) is use for processing the data. The data is prepared by selecting 1-hr time series segments with an overlap of 50%. Each 1-hr segment is divided into 13 segments with 75% overlap to reduce variance of the power spectral density (PSD) estimates. After removing the mean, trend and instrument response, 10% cosine taper is applied to the ends of the time series to reduce the spectral leakage in the resulting Fast Fourier Transform (FFT). After computing the PSD of each time series segment the results are converted to ground acceleration to compare with the NLNM and NHNM. After calculating the PSDs and PDFs, first results show that the main features of noise are coherent in general with the new low-noise model (NLNM) and new high-noise model (NHNM) of Peterson noise models but different at few localities. These features are cultural noise (T=0.1-1s, noise source: traffic, machinery) and microseisms that are classified as Double Frequency Peak (DFP, T=4-8s, noise source: ocean waves) and Single Frequency Peak (SFP, T=10-20s, noise source: shallow coastal waters). Before the noise characterization, the usage and properties of PQLX, its inputs and outputs, arrangement of the suitable response function format, organization of the data set's header informations etc. are investigated and applied. In order to investigate the noise characteristics in the basin and its surroundings, PSD mode values are used for the cultural noise and microseism periods and noise distribution maps are prepared for annual, seasonal and diurnal variations by using GMT (Generic Mapping Tools). To observe the annual noise changes, PSD mode values for the 3 different period band have mapped for the year of 2011. For the cultural noise band (T=0.1-1s), it is clearly seen that the noise level is higher than the other bands (DFP, SFP) and high noise propagates from the coast region towards the basin. For the DFP band (T=4-8s), relatively higher noise level stands near the border of the basin and also cay station which has always the highest noise level in the basin. For the SFP band (T=10-20s), there is a sharp noise decreasing as near as 30 dB through the whole basin, but still middle of the basin has higher noise values. To observe the seasonal noise changes, summer months (June, July, August 2011) and winter months (December 2011, January-February 2012) are processed. In the cultural noise band, noise distribution in summer is more extensive and propagates from all coastal side into the basin; in winter, high noise level distribution remains only on the coastal side. Contrarily, for the DFP band, noise variationss are observed only on the borders of the basin except cay in summer, while almost whole study xxi area has affected by the high noise such as -120 dB and -130 dB in winter. Lastly, for the SFP band, again there is a sharp noise level decreasing for both seasons, but it is seen that, in winter, especially Adana Basin and around the Taurus Mountain (Northwest of the study area) has relatively high noise values. In addition to these noise maps, to observe the seasonal changes with different graphs, spectrograms were analysed for two different seasons as wet and dry seasons. To observe the daily noise changes, the day (06:00-20:00) and the night (20:00-06:00) times data are mapped. For the cultural noise, the day time shows high noise levels especially near the coast and in the basin region. This high noise level reduces about 10-20 dB at the night times. For the DFP, there is no significant variation between day and night times. At SFP both for the day and the night times, the noise levels in the basin are higher in comparison to mountain sides. The relatively high noise levels in the basin are spread to wider area in the day time when compared to the night times. Consequently, in daily basis, the significant variations occur at cultural noise levels, almost no variation is observed at SFP, and slight variations are observed at DFP periods. In addition to three specific period band that defined above, for the 0.5-3s band, we observe the DFP changes during a year and half yearly. It is seen that, local sea wave activity affects the noise level, bathimetry changes could also be a good reason for these changes. Besides the noise map interpretations, some other investigations are also studied and some are briefly mentioned as follows. Noise level difference between the coastal and the crustal based stations which installed on the same geological structure is studied by the analysis of the spectrograms. Also, as three-component data sets are available for the KOERI stations, those mode values are graphed for the seven stations and it is seen that the horizontal components (E, N) have higher noise levels with respect to vertical (Z) component in high periods. Vertical-component PSD mode curves for 17 stations are coherent with the Peterson noise models. The Adana Basin mode high- and low- noise models are estimated which will provide useful information before the installation of any station and also in earthquake magnitude interpretations. In this study, unfortunately it is observed that at some stations the data quality is poor due to the interruption of data transfer, mass recenter and similar reasons, therefore significant part of the data could not be used in processing. For the future studies, the PSD calculations for the year 2012 and for the horizontal components of the time series are under progress. Afterwards array processing and the horizontal to vertical spectral ratio (HVSR) studies will be performed for the region for further characterization of both noise and subsurface structure. 101

Published

2016

8. Crust-Correction and Measurement of Finite-Frequency Travel Time Residuals for Body-Wave Tomography in Scandinavia.

Author

Bulut, Nevra, Maupin, Valérie, and Thybo, Hans

Subjects

*SEISMIC tomography, *SHEAR waves, *TOMOGRAPHY, *SEISMIC arrays, *INFORMATION storage & retrieval systems, *LITHOSPHERE

Abstract

The ScanArray experiment is an extensive collaboration between the universities of Aarhus, Bergen, Copenhagen, Karlsruhe, Leicester, Oslo, and Uppsala, Istanbul Technical University, GFZ Potsdam, and NORSAR, that focuses on the structure of the lithosphere and upper mantle processes below Scandinavia. The experiment has acquired broadband seismic data on a dense array of temporary seismometers over a period of four years. This data will be subject to interpretation and inversion by a wide variety of seismological methods.Here we apply finite-frequency body-wave tomography to determine the velocity structure of the upper mantle in order to provide background for understanding the mechanisms responsible for the topography of the Scandinavian region. Our interpretation will help determining if the crust and lithosphere are in isostatic equilibrium or dynamic forces actively affect the high topography in the region. We will use finite-frequency residuals of P and S waves from teleseismic earthquakes at epicentral distances between 30° to 104° and with magnitudes of at least 5.5, gathered on 200 broadband seismic stations installed in Norway, Sweden and Finland during the period of 2012-2017.Since the quality of the tomography models directly depends on the precision of the travel time residuals, it is crucial to measure accurate relative travel times. Therefore, in this first part of the study, we pay particular attention to appropriate crustal corrections and procedures for measurement of finite-frequency travel time residuals. Crustal correction will be based on application of the reflectivity method at each station, ensuring that the proper frequency dependence of the corrections is taken into account. Corrections will be applied on low- and high- frequency bands separately. This new crustal correction procedure will be implemented in the data processing routine suggested by Kolstrup et al. (2015), which will be used to estimate finite-frequency travel time residuals using a combination of the Iterative Cross-Correlation and Stack (ICCS) algorithm and the Multi-Channel Cross-Correlation (MCCC) method. At a later stage, finite-frequency body-wave tomography method will be applied and the final results will be discussed in relation to other studies of the Scandinavian upper mantle. [ABSTRACT FROM AUTHOR]

Published

2019