scholarly journals Anisotropy, repeating earthquakes, and seismicity associated with the 2008 eruption of Okmok volcano, Alaska

2021 ◽  
Author(s):  
J Johnson ◽  
S Prejean ◽  
Martha Savage ◽  
John Townend
Keyword(s):  
Cross Correlation ◽  
Normal Fault ◽  
Processing Parameters ◽  
Temporal Variations ◽  
Geothermal Field ◽  
Double Difference ◽  
Magma Body ◽  
Seismic Properties ◽  
Northern Portion ◽  
Okmok Volcano

We use shear wave splitting (SWS) analysis and double-difference relocation to examine temporal variations in seismic properties prior to and accompanying magmatic activity associated with the 2008 eruption of Okmok volcano, Alaska. Using bispectrum cross-correlation, a multiplet of 25 earthquakes is identified spanning five years leading up to the eruption, each event having first motions compatible with a normal fault striking NE-SW. Cross-correlation differential times are used to relocate earthquakes occurring between January 2003 and February 2009. The bulk of the seismicity prior to the onset of the eruption on 12 July 2008 occurred southwest of the caldera beneath a geothermal field. Earthquakes associated with the onset of the eruption occurred beneath the northern portion of the caldera and started as deep as 13 km. Subsequent earthquakes occurred predominantly at 3 km depth, coinciding with the depth at which the magma body has been modeled using geodetic data. Automated SWS analysis of the Okmok catalog reveals radial polarization outside the caldera and a northwest-southeast polarization within. We interpret these polarizations in terms of a magma reservoir near the center of the caldera, which we model with a Mogi point source. SWS analysis using the same input processing parameters for each event in the multiplet reveals no temporal changes in anisotropy over the duration of the multiplet, suggesting either a short-term or small increase in stress just before the eruption that was not detected by GPS, or eruption triggering by a mechanism other than a change of stress in the system. © 2010 by the American Geophysical Union.

scholarly journals Anisotropy, repeating earthquakes, and seismicity associated with the 2008 eruption of Okmok volcano, Alaska

2021 ◽  
Author(s):  
J Johnson ◽  
S Prejean ◽  
Martha Savage ◽  
John Townend
Keyword(s):  
Cross Correlation ◽  
Normal Fault ◽  
Processing Parameters ◽  
Temporal Variations ◽  
Geothermal Field ◽  
Double Difference ◽  
Magma Body ◽  
Seismic Properties ◽  
Northern Portion ◽  
Okmok Volcano

We use shear wave splitting (SWS) analysis and double-difference relocation to examine temporal variations in seismic properties prior to and accompanying magmatic activity associated with the 2008 eruption of Okmok volcano, Alaska. Using bispectrum cross-correlation, a multiplet of 25 earthquakes is identified spanning five years leading up to the eruption, each event having first motions compatible with a normal fault striking NE-SW. Cross-correlation differential times are used to relocate earthquakes occurring between January 2003 and February 2009. The bulk of the seismicity prior to the onset of the eruption on 12 July 2008 occurred southwest of the caldera beneath a geothermal field. Earthquakes associated with the onset of the eruption occurred beneath the northern portion of the caldera and started as deep as 13 km. Subsequent earthquakes occurred predominantly at 3 km depth, coinciding with the depth at which the magma body has been modeled using geodetic data. Automated SWS analysis of the Okmok catalog reveals radial polarization outside the caldera and a northwest-southeast polarization within. We interpret these polarizations in terms of a magma reservoir near the center of the caldera, which we model with a Mogi point source. SWS analysis using the same input processing parameters for each event in the multiplet reveals no temporal changes in anisotropy over the duration of the multiplet, suggesting either a short-term or small increase in stress just before the eruption that was not detected by GPS, or eruption triggering by a mechanism other than a change of stress in the system. © 2010 by the American Geophysical Union.

scholarly journals Fluid activity detection in geothermal areas using a single seismic station by monitoring horizontal-to-vertical spectral ratios

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Kyosuke Okamoto ◽  
Hiroshi Asanuma ◽  
Hiro Nimiya
Keyword(s):  
Carbon Capture ◽  
Seismic Station ◽  
Carbon Capture And Storage ◽  
Fluid Flows ◽  
Temporal Variations ◽  
Geothermal Field ◽  
Spectral Ratios ◽  
Subsurface Structures ◽  
Geothermal Fields ◽  
Single Station

AbstractSubsurface structure survey based on horizontal-to-vertical (H/V) spectral ratios is widely conducted. The major merit of this survey is its convenience to obtain a stable result using a single station. Spatial variations of H/V spectral ratios are well-known phenomena, and it has been used to estimate the spatial fluctuation in subsurface structures. It is reasonable to anticipate temporal variations in H/V spectral ratios, especially in areas like geothermal fields, carbon capture and storage fields, etc., where rich fluid flows are expected, although there are few reports about the temporal changes. In Okuaizu Geothermal Field (OGF), Japan, dense seismic monitoring was deployed in 2015, and continuous monitoring has been consistent. We observed the H/V spectral ratios in OGF and found their repeated temporary drops. These drops seemed to be derived from local fluid activities according to a numerical calculation. Based on this finding, we examined a coherency between the H/V spectral ratios and fluid activities in OGF and found a significance. In conclusion, monitoring H/V spectral ratios can enable us to grasp fluid activities that sometimes could lead to a relatively large seismic event.

scholarly journals Multiscale Analysis of DInSAR Measurements for Multi-Source Investigation at Uturuncu Volcano (Bolivia)

2019 ◽  
Vol 11 (6) ◽  
pp. 703 ◽  
Author(s):  
Andrea Barone ◽  
Maurizio Fedi ◽  
Pietro Tizzani ◽  
Raffaele Castaldo
Keyword(s):  
Multiscale Analysis ◽  
Cross Correlation ◽  
Ground Deformation ◽  
Vertical Component ◽  
Central Zone ◽  
Time Interval ◽  
Volcanic Complex ◽  
Magma Body ◽  
Deep Source ◽  
Good Agreement

Uturuncu volcano (southwestern Bolivia) is localized within one of the largest updoming volcanic zones, the Altiplano Puna Volcanic Complex (APVC). In several geodetic studies the observed uplift phenomenon is analyzed and modeled by considering a deep source, related to the Altiplano Puna Magma Body (APMB). In this framework, we perform a multiscale analysis on the 2003–2010 ENVISAT satellite data to investigate the existence of a multi-source scenario for this region. The proposed analysis is based on Cross-correlation and Multiridge method, pointing out the spatial and temporal multiscale properties of the deformation field. In particular, we analyze the vertical component of ground deformation during two time interval: within the 2005–2008 time interval an inflating source at 18.7 km depth beneath the central zone of the APVC is retrieved; this result is in good agreement with those proposed by several authors for the APMB. Between August 2006 and February 2007, we identify a further inflating source at 4.5 km depth, beneath Uturuncu volcano; the existence of this latter, located just below the 2009–2010 seismic swarm, is supported by petrological, geochemical, and geophysical evidence, indicating as a possible interpretative scenario the action of shallow, temporarily trapped fluids.

Seismotectonic setting of Santorini-Amorgos zone and the surrounding area revealed from crustal earthquakes relocation and Vp/Vs distribution

2020 ◽  
Author(s):  
Ratri Andinisari ◽  
Konstantinos I. Konstantinou ◽  
Pratul Ranjan ◽  
Qori F. Hermawan
Keyword(s):  
Cross Correlation ◽  
Double Difference ◽  
Surrounding Area ◽  
Submarine Volcano ◽  
S Wave ◽  
Offshore Area ◽  
Crustal Earthquakes ◽  
Wave Travel ◽  
Seismic Networks ◽  
Earthquake Clusters

<p>The Santorini-Amorgos zone represents right-lateral transtensional regime from NE of Santorini to the south of Amorgos which also hosts Kolumbo submarine volcano. A total number of 1869 crustal events from 2002 to 2019 were recorded by permanent and temporal seismic networks deployed in southern Aegean. Absolute locations of these events were obtained by utilizing the probabilistic nonlinear algorithm NonLinLoc. Precise relative relocation by using double-difference algorithm with catalog and cross-correlation differential times was later performed, resulting in 1455 locations with horizontal and vertical uncertainties of less than 0.3 km. Clusters of earthquakes relocated between Naxos and Paros as well as north of Astypalaia do not coincide with any fault in the area. Similarly, the relocated crustal events across Santorini-Amorgos zone show that most of the earthquake clusters do not coincide with any of the existing faults. The distribution of Vp/Vs ratios in the area were investigated based on the P and S-wave travel times of all the events. Vp/Vs ratios in the area vary between 1.67 and 2.03 with errors less than 0.04. The highest Vp/Vs values were found to be distributed in the area between Naxos and Paros. Other areas with notably high Vp/Vs ratio are north of Santorini, Anydros, west of Amorgos, offshore area south of the easternmost tip of Amorgos, and the island of Astypalaia. These mentioned areas were also rich in seismic activities during the period of study. The high Vp/Vs ratios in the region of high seismicity signifies that these events were likely related to the migration of magmatic fluids to the surface and may not be caused by the existing faults.</p>

scholarly journals Discriminating Between Spatial and  Temporal Variations in Seismic  Anisotropy at Active Volcanoes

2021 ◽  
Author(s):  
◽  
Jessica Helen Johnson
Keyword(s):  
Shear Wave ◽  
Seismic Anisotropy ◽  
Shear Wave Splitting ◽  
Temporal Variations ◽  
Temporal Changes ◽  
Stable Region ◽  
Strong Anisotropy ◽  
Wave Splitting ◽  
Okmok Volcano ◽  
Active Volcanoes

<p>This thesis addresses the measurement and interpretation of seismic anisotropy around active volcanoes via shear wave splitting analysis. An overpressured magma reservoir will exert a stress on the surrounding country rock that may or may not be manifest as observable strain. Shear wave splitting analysis can be a useful indicator of stress in the crust and hence, the pressure induced by magma movement. Changes in shear wave splitting have already been observed at Mt. Ruapehu following eruptions in 1995/1996 and are inferred to be caused by changes in local stress in response to magma pressure. One of the main problems with the interpretation of temporal changes in shear wave splitting is the possibility of spatial variations being sampled along differing raypaths and being interpreted as temporal changes. Using a dense observational network and an automated shear wave splitting analysis, we examine local earthquakes occurring in 2008 within 100 km of Mt. Ruapehu. We note a strong azimuthal dependence of the fast direction of anisotropy (phi) and so introduce a spatial averaging technique and a two-dimensional tomography of recorded delay times (dt), to observe the spatial variation in more detail. Using this new method of mapping shear wave splitting parameters, we have created a benchmark of spatial variations in shear wave anisotropy around Mt. Ruapehu, against which future temporal changes may be measured. The observed anisotropy is used to define regions in which phi agrees with stress estimations from focal mechanism inversions, suggesting stress-induced anisotropy, and those in which phi aligns with structural features such as fault strikes, suggesting structural anisotropy. Data from past deployments of three-component seismometers have been analysed in the same way as those recorded during the 2008 experiment and the results compared. We identify a stable region of strong anisotropy, interpreted to be caused by schistose mineral alignment, and a transient region of strong anisotropy centred on the volcano during the major magmatic eruption of 1995. We also introduce a method of analysing temporal variations in seismic anisotropy at active volcanoes by using tight clusters of earthquakes and highly correlated multiplets. At Mt. Ruapehu, changes in shear wave splitting parameters associated with the 2006 and 2007 phreatic eruptions are detected using a cluster of earthquakes to the west of the volcano. Similar analyses using another cluster and multiplets from the stable region of strong anisotropy do not reveal temporal changes, although examination of the waveform codas of the repeating earthquakes reveals systematic changes that we interpret as being caused by seismic scatterers associated with the 2006 and 2007 eruptions. These scatterers appear to contaminate the shear wave coda and so inhibit the detection of any subtle changes in shear wave splitting parameters. Finally, we apply some of these methods to data from the 2008 eruption of Okmok volcano, Alaska. Shear wave splitting analysis at Okmok reveals a change in anisotropy associated with the 2008 eruption. This change however, is attributed to a change in dominant hypocentre location. Multiplet analysis at Okmok volcano reveals a similar scatterer contamination of the shear wave arrival. This spurious phase is interpreted to be an S to P conversion from interaction with the magma reservoir.</p>

scholarly journals Spatiotemporal patterns of microseismicity for the identification of active fault structures using seismic waveform cross-correlation and double-difference relocation

2017 ◽  
Author(s):  
Βασίλειος Καπετανίδης
Keyword(s):  
Cross Correlation ◽  
Active Fault ◽  
Spatiotemporal Patterns ◽  
Double Difference ◽  
Seismic Waveform ◽  
Waveform Cross Correlation ◽  
Fault Structures

Οι σεισμικές ακολουθίες χαρακτηρίζονται συχνά από διακριτά μοτίβα, όπως χωρικές και χρονικές συστάδες, μονόπλευρη, αμφίπλευρη ή ακτινική μετανάστευση υποκέντρων και εξάρσεις στο ρυθμό σεισμικότητας. Αυτά εξαρτώνται από τη γεωμετρία του δικτύου ρηγμάτων, το καθεστώς τάσεων περιφερειακής κλίμακας με τοπικές ανωμαλίες εξαιτίας ανακατανομής τάσεων ύστερα από ισχυρά γεγονότα ή ασεισμικούς παράγοντες όπως ερπυσμό και διάχυση ρευστών υπό πίεση. Είναι σύνηθες στη χωρικά συσταδοποιημένη σεισμικότητα να εμφανίζονται σεισμοί με όμοιες εστιακές παραμέτρους (σμηνοσεισμοί, ή multiplets), οι οποίοι παράγουν όμοιες σεισμικές αναγραφές. Στην παρούσα διδακτορική διατριβή αξιοποιείται το φαινόμενο της ομοιότητας κυματομορφών με σκοπό τη βελτίωση της χωροχρονικής κατανομής των σεισμών ενός καταλόγου, τόσο σε ποσότητα δεδομένων, μέσω μεθόδων ημιαυτόματης ανίχνευσης και εντοπισμού, όσο και σε ποιότητα, εφαρμόζοντας επαναπροσδιορισμό υψηλής ευκρίνειας με τη μέθοδο των διπλών διαφορών που ελαχιστοποιεί τις αβεβαιότητες των σχετικών υποκεντρικών θέσεων. Η προτιμώμενη μέθοδος για τη μέτρηση της ομοιότητας κυματομορφών είναι το μέγιστο της συνάρτησης ετεροσυσχέτισης στο πεδίο του χρόνου. Τα χαρακτηριστικά της εξετάζονται ως προς διάφορες παραμέτρους, όπως τα συχνοτικά φίλτρα που εφαρμόζονται, το μήκος παραθύρου και η διάρκεια της σεισμικής πηγής, καθώς και τη βέλτιστη τιμή κατωφλίου για συσταδοποίηση με σύνδεση του «πλησιέστερου γείτονα». Αναπτύχθηκε μια ημιαυτόματη μέθοδος προσδιορισμού χρόνων άφιξης, βασισμένη στην τεχνική του «ανιχνευτή συσχέτισης» που αξιοποιεί την ομοιότητα κυματομορφών σε πολλαπλούς σταθμούς. Η μέθοδος αυτή έχει τροποποιηθεί σε έναν υβριδικό αλγόριθμο που συνδυάζει την αυξημένη ανιχνευσιμότητα ενός μεμονωμένου σταθμού με έναν υψηλής ευαισθησίας αυτόματο αλγόριθμο προσδιορισμού του χρόνου άφιξης σεισμικών φάσεων, ο οποίος βασίζεται στο Κριτήριο Πληροφορίας του Akaike και σε στατιστική ανώτερης τάξεως (κύρτωση και λοξότητα). Περιγράφεται, επίσης, μία μέθοδος προσδιορισμού του μεγέθους σεισμικής ροπής μέσα από φασματική ανάλυση, με έμφαση σε τροποποιήσεις που επιτρέπουν τον υπολογισμό του σε τοπικούς μικροσεισμούς με στενό συχνοτικό εύρος και χαμηλό λόγο σήματος προς θόρυβο. Οι αλγόριθμοι που αναπτύχθηκαν επιτρέπουν τον δεκαπλασιασμό της ποσότητας σεισμών ενός σεισμικού καταλόγου και τη βελτίωση της πληρότητάς του κατά περίπου μία τάξη μεγέθους.Παρουσιάζονται διάφορες μελέτες περιπτώσεων που περιλαμβάνουν πρότυπα μετασεισμικών ακολουθιών (όπως για τους σεισμούς της Ανδραβίδας το 2008, της Κεφαλονιάς το 2014 και της Λευκάδας το 2015) καθώς και σεισμικών σμηνών (όπως στη Λίμνη Τριχωνίδα το 2007, την Οιχαλία το 2011 και την Ελίκη το 2013). Η κύρια περιοχή μελέτης είναι ο δυτικός Κορινθιακός Κόλπος, με ειδική έμφαση σε σεισμούς που καταγράφηκαν την περίοδο 2000-2007 από το τοπικό δίκτυο Corinth Rift Laboratory (CRL). Οι επαναπροσδιορισμένοι κατάλογοι, ύστερα από χωρική συσταδοποίηση και διαχωρισμό σε διαδοχικές χρονικές περιόδους, διερευνώνται μέσω πολλαπλών εγκάρσιων τομών και χωροχρονικών προβολών. Η εξέλιξη του ιστορικού των σμηνοσεισμών δίνει μία εικόνα για τον τρόπο με τον οποίο εξαπλώνεται η σεισμικότητα σε νέα τμήματα ρηγμάτων που δεν είχαν διαρρηχθεί, την προϋπάρχουσα δραστηριότητα σε περιοχές που αργότερα έδωσαν ισχυρές σεισμικές συστάδες και την επαναλαμβανόμενη σεισμικότητα σε τμήματα ρηξιγενών ζωνών. Όπου τα δεδομένα το επιτρέπουν, κατασκευάζονται σύνθετοι μηχανισμοί γένεσης για χωρικές συστάδες ή ομάδες σμηνοσεισμών που βοηθούν συμπληρωματικά στην ερμηνεία της χωρικής ανάλυσης και τον προσδιορισμό των ενεργοποιημένων ρηξιγενών δομών. Αναζητούνται μοτίβα χωροχρονικής σεισμικής μετανάστευσης που αποκαλύπτουν την πιθανή επίδραση ρευστών κατά τη διάρκεια σεισμικών σμηνών και προσδιορίζονται παράμετροι όπως η υδραυλική διαχυτικότητα και η ταχύτητα μετανάστευσης. Τέλος, εξετάζεται η συνεισφορά ασεισμικών παραγόντων μέσα από μοντέλα ETAS (Μετασεισμική Ακολουθία Σποραδικού Τύπου) που παρέχουν, επιπροσθέτως, πληροφορία για την παραγωγικότητα μετασεισμών και τον ρυθμό απόσβεσης.

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