CRUSTAL STRESS FIELD IN THE ACTIVE SEISMIC ZONES IN AND AROUND VRANCEA AREA, ROMANIA

The mechanisms involved in the geodynamic evolution and the links with present day seismicity in and around an active orogenic area such as Vrancea area, located at the arc bend of the South-Eastern Carpathians in Romania, are of fundamental importance for studies concerning the seismic hazard asses...

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Main Authors: ANDREI BĂLĂ, MIRCEA RADULIAN, DRAGOȘ TOMA-DĂNILĂ
Format: Text
Language:English
Published: Zenodo 2021
Subjects:
stress field, crustal model, Moho discontinuity, tectonic structure, geodynamic behavior
Fuchs
Mueller
Hippolyte
Custodio
Iceland
Online Access:https://dx.doi.org/10.5281/zenodo.4548645
https://zenodo.org/record/4548645
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topic stress field, crustal model, Moho discontinuity, tectonic structure, geodynamic behavior
spellingShingle stress field, crustal model, Moho discontinuity, tectonic structure, geodynamic behavior
ANDREI BĂLĂ
MIRCEA RADULIAN
DRAGOȘ TOMA-DĂNILĂ
CRUSTAL STRESS FIELD IN THE ACTIVE SEISMIC ZONES IN AND AROUND VRANCEA AREA, ROMANIA
topic_facet stress field, crustal model, Moho discontinuity, tectonic structure, geodynamic behavior
description The mechanisms involved in the geodynamic evolution and the links with present day seismicity in and around an active orogenic area such as Vrancea area, located at the arc bend of the South-Eastern Carpathians in Romania, are of fundamental importance for studies concerning the seismic hazard assessment in Romania. The task is attempted through the partitioning of seismic events and corresponding stress at crustal level in and around the Vrancea zone. We start in this respect with the configuration of seismogenic zones as defined in previous investigations and then we use all the available and reliable earthquake focal mechanisms to study present-day deformation and stress. The goal of the present paper is to investigate the stress field characteristics in relation to the specific geotectonic and seismogenic zones in Vrancea and neighboring areas. The principal stress components are computed by inverting the fault plane solutions provided by a completed and updated catalogue for the crustal earthquakes recorded from 1952 up to 2012. Our investigation is justified to the extent that the basic hypothesis of adequately representing the seismic area partitioning by individual clusters of events is relevant at the scale of each earthquake-prone area and from statistical point of view (minimum 25 – 30 events/active zone). The results obtained through the inversion procedure show that the focal mechanisms are kinematically compatible with the selected clusters (earthquake-prone areas) despite an apparent scattering of the fault plane solutions. For example, the specific thrust faulting regime (compression) in the seismogenic zones in the Vrancea area and extensional stress regime as we go away from the Vrancea area. Note also the general lack of strike-slip faulting, except the seismogenic area located along the Peceneaga–Camena fault, which separates the Scythian platform to the north-east from the Moesian platform to the southwest. All the relevant information obtained in the process of inversion is further used in order to analyze the geodynamic evolution of the active seismic zones around Vrancea area and to try to improve the understanding of some geophysical observations that still do not have a satisfactory explanation in the light of existing models. The assessment of the stress field configuration based on improved and updated focal mechanism data led to a real improvement of the shape of the regional field as computed in the last version of the World Stress Map (WSM 2016). : {"references": ["B\u0102L\u0102, A., TOMA\u2011D\u0102NIL\u0102, D., RADULIAN, M. (2019), Focal mechanisms in Romania: statistical features representative for earthquake\u2011prone areas and spatial correlations with tectonic provinces. Acta Geodaetica et Geophysica, 54, pp. 263\u2013286, https://doi.org/ 10.1007/s40328-019-00260-w.", "BOTT, M.H.P. (1959), The mechanics of oblique-slip faulting. Geological Magazine, 96, pp. 109\u2013117.", "DELVAUX, D., MOEYS, R., STAPEL, G., PETIT, C., LEVI, K., MIROSHNICH, K., RUZHICH, V., SANKOV, V. (1997), Paleostress reconstructions and geodynamics of the Baikal region, Central Asia. Part 2. Cenozoic rifting. Tectonophysics, 282, pp. 1\u201338.", "FOJT\u00cdKOV\u00c1, L., VAVRY\u010cUK, V. (2018), Tectonic stress regime in the 2003\u20132004 and 2012\u20132015 earthquake swarms in the Ubaye Valley, French Alps. Pure Appl. Geophys., 175.", "HEIDBACH, O., REINECKER, J., TINGAY, M., MULLER, B., SPERNER, B., FUCHS, K., WENZEL, F. (2007), Plate boundary forces are not enough: Second- and third-order stress patterns highlighted in the World Stress Map database. Tectonics, 26, TC6014.", "HEIDBACH, O., TINGAY, M., BARTH, A., REINECKER, J., KURFESS, D., MUELLER, B. (2008), The 2008 database release of the World Stress Map Project. Deutsches GeoForschungsZentrum GFZ. https://doi.org/10.1594/GFZ.WSM.Rel2008.", "HEIDBACH, O., CUSTODIO, S., KINGDON, A., MARIUCCI, M.T., MONTONE, P., M\u00dcLLER, B., PIERDOMINICI, S., RAJABI, M., REINECKER, J., REITER, K., TINGAY, M., WILLIAMS, J., ZIEGLER, M. (2016), Stress Map of the Mediterranean and Central Europe, GFZ Data Services.", "HIPPOLYTE, J.-C. (2002), Geodynamics of Dobrogea (Romania): New constraints on the evolution of the Tornquist - Teisseyre Line, the Black Sea and the Carpathians. Tectonophysics, 357, pp. 33\u201353.", "LUND, B., SLUNGA, R. (1999), Stress tensor inversion using detailed microearthquake information and stability constraints: Application to Olfus in southwest Iceland. Journal of Geophysical Research, 104, B7, pp. 14947\u201314964.", "MALI\u021aA, Z., R\u0102DULESCU, F. (2010), Focal mechanisms of some crustal earthquakes that occurred in the Pannonian depression (Arad \u2013 south Timisoara area), the Moesian platform and North Dobrogean Orogen. Rev. Roum. Geophys., 54, pp. 19\u201337.", "MICHAEL, A.J. (1984), Determination of stress from slip data: Faults and folds. J. Geophys. Res., 89, pp. 11.517\u201311.526.", "RADULIAN, M., B\u0102L\u0102, A., POPESCU, E., TOMA-D\u0102NIL\u0102, D. (2018), Earthquake mechanism and characterization of seismogenic zones in south-eastern part of Romania. Annals of Geophysics, 61(1), SE108.", "RADULIAN, M., B\u0102L\u0102, A., ARDELEANU, L., TOMA-D\u0102NIL\u0102, D., PETRESCU, L., POPESCU, E. (2019), Revised catalogue of earthquake mechanisms for the events occurred in Romania until the end of twentieth century: REFMC. Acta Geodaetica et Geophysica, 54, pp. 3\u201318.", "S\u0102NDULESCU, M. (1984), Geotectonics of Romania (in Romanian), Ed. Tehnic\u0103, pp. 334, Bucharest, Romania.", "VAVRY\u010cUK, V. (2015), Moment tensor decompositions revisited. Journal of Seismology, 19, 1, pp. 231\u2013252.", "ZOBACK, M.L. (1992), First and second order patterns of stress in the lithosphere: The World Stress Map Project. J. Geophys. Res., 97, pp. 11703\u201311728."]}
format Text
author ANDREI BĂLĂ
MIRCEA RADULIAN
DRAGOȘ TOMA-DĂNILĂ
author_facet ANDREI BĂLĂ
MIRCEA RADULIAN
DRAGOȘ TOMA-DĂNILĂ
author_sort ANDREI BĂLĂ
title CRUSTAL STRESS FIELD IN THE ACTIVE SEISMIC ZONES IN AND AROUND VRANCEA AREA, ROMANIA
title_short CRUSTAL STRESS FIELD IN THE ACTIVE SEISMIC ZONES IN AND AROUND VRANCEA AREA, ROMANIA
title_full CRUSTAL STRESS FIELD IN THE ACTIVE SEISMIC ZONES IN AND AROUND VRANCEA AREA, ROMANIA
title_fullStr CRUSTAL STRESS FIELD IN THE ACTIVE SEISMIC ZONES IN AND AROUND VRANCEA AREA, ROMANIA
title_full_unstemmed CRUSTAL STRESS FIELD IN THE ACTIVE SEISMIC ZONES IN AND AROUND VRANCEA AREA, ROMANIA
title_sort crustal stress field in the active seismic zones in and around vrancea area, romania
publisher Zenodo
publishDate 2021
url https://dx.doi.org/10.5281/zenodo.4548645
https://zenodo.org/record/4548645
long_lat ENVELOPE(-68.666,-68.666,-67.233,-67.233)
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ENVELOPE(-67.233,-67.233,-67.533,-67.533)
geographic Fuchs
Mueller
Hippolyte
Custodio
geographic_facet Fuchs
Mueller
Hippolyte
Custodio
genre Iceland
genre_facet Iceland
op_relation https://dx.doi.org/10.5281/zenodo.4548646
op_rights Open Access
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op_doi https://doi.org/10.5281/zenodo.4548645
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spelling ftdatacite:10.5281/zenodo.4548645 2023-05-15T16:53:27+02:00 CRUSTAL STRESS FIELD IN THE ACTIVE SEISMIC ZONES IN AND AROUND VRANCEA AREA, ROMANIA ANDREI BĂLĂ MIRCEA RADULIAN DRAGOȘ TOMA-DĂNILĂ 2021 https://dx.doi.org/10.5281/zenodo.4548645 https://zenodo.org/record/4548645 en eng Zenodo https://dx.doi.org/10.5281/zenodo.4548646 Open Access Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 info:eu-repo/semantics/openAccess CC-BY stress field, crustal model, Moho discontinuity, tectonic structure, geodynamic behavior Text Journal article article-journal ScholarlyArticle 2021 ftdatacite https://doi.org/10.5281/zenodo.4548645 https://doi.org/10.5281/zenodo.4548646 2021-11-05T12:55:41Z The mechanisms involved in the geodynamic evolution and the links with present day seismicity in and around an active orogenic area such as Vrancea area, located at the arc bend of the South-Eastern Carpathians in Romania, are of fundamental importance for studies concerning the seismic hazard assessment in Romania. The task is attempted through the partitioning of seismic events and corresponding stress at crustal level in and around the Vrancea zone. We start in this respect with the configuration of seismogenic zones as defined in previous investigations and then we use all the available and reliable earthquake focal mechanisms to study present-day deformation and stress. The goal of the present paper is to investigate the stress field characteristics in relation to the specific geotectonic and seismogenic zones in Vrancea and neighboring areas. The principal stress components are computed by inverting the fault plane solutions provided by a completed and updated catalogue for the crustal earthquakes recorded from 1952 up to 2012. Our investigation is justified to the extent that the basic hypothesis of adequately representing the seismic area partitioning by individual clusters of events is relevant at the scale of each earthquake-prone area and from statistical point of view (minimum 25 – 30 events/active zone). The results obtained through the inversion procedure show that the focal mechanisms are kinematically compatible with the selected clusters (earthquake-prone areas) despite an apparent scattering of the fault plane solutions. For example, the specific thrust faulting regime (compression) in the seismogenic zones in the Vrancea area and extensional stress regime as we go away from the Vrancea area. Note also the general lack of strike-slip faulting, except the seismogenic area located along the Peceneaga–Camena fault, which separates the Scythian platform to the north-east from the Moesian platform to the southwest. All the relevant information obtained in the process of inversion is further used in order to analyze the geodynamic evolution of the active seismic zones around Vrancea area and to try to improve the understanding of some geophysical observations that still do not have a satisfactory explanation in the light of existing models. The assessment of the stress field configuration based on improved and updated focal mechanism data led to a real improvement of the shape of the regional field as computed in the last version of the World Stress Map (WSM 2016). : {"references": ["B\u0102L\u0102, A., TOMA\u2011D\u0102NIL\u0102, D., RADULIAN, M. (2019), Focal mechanisms in Romania: statistical features representative for earthquake\u2011prone areas and spatial correlations with tectonic provinces. Acta Geodaetica et Geophysica, 54, pp. 263\u2013286, https://doi.org/ 10.1007/s40328-019-00260-w.", "BOTT, M.H.P. (1959), The mechanics of oblique-slip faulting. Geological Magazine, 96, pp. 109\u2013117.", "DELVAUX, D., MOEYS, R., STAPEL, G., PETIT, C., LEVI, K., MIROSHNICH, K., RUZHICH, V., SANKOV, V. (1997), Paleostress reconstructions and geodynamics of the Baikal region, Central Asia. Part 2. Cenozoic rifting. Tectonophysics, 282, pp. 1\u201338.", "FOJT\u00cdKOV\u00c1, L., VAVRY\u010cUK, V. (2018), Tectonic stress regime in the 2003\u20132004 and 2012\u20132015 earthquake swarms in the Ubaye Valley, French Alps. Pure Appl. Geophys., 175.", "HEIDBACH, O., REINECKER, J., TINGAY, M., MULLER, B., SPERNER, B., FUCHS, K., WENZEL, F. (2007), Plate boundary forces are not enough: Second- and third-order stress patterns highlighted in the World Stress Map database. Tectonics, 26, TC6014.", "HEIDBACH, O., TINGAY, M., BARTH, A., REINECKER, J., KURFESS, D., MUELLER, B. (2008), The 2008 database release of the World Stress Map Project. Deutsches GeoForschungsZentrum GFZ. https://doi.org/10.1594/GFZ.WSM.Rel2008.", "HEIDBACH, O., CUSTODIO, S., KINGDON, A., MARIUCCI, M.T., MONTONE, P., M\u00dcLLER, B., PIERDOMINICI, S., RAJABI, M., REINECKER, J., REITER, K., TINGAY, M., WILLIAMS, J., ZIEGLER, M. (2016), Stress Map of the Mediterranean and Central Europe, GFZ Data Services.", "HIPPOLYTE, J.-C. (2002), Geodynamics of Dobrogea (Romania): New constraints on the evolution of the Tornquist - Teisseyre Line, the Black Sea and the Carpathians. Tectonophysics, 357, pp. 33\u201353.", "LUND, B., SLUNGA, R. (1999), Stress tensor inversion using detailed microearthquake information and stability constraints: Application to Olfus in southwest Iceland. Journal of Geophysical Research, 104, B7, pp. 14947\u201314964.", "MALI\u021aA, Z., R\u0102DULESCU, F. (2010), Focal mechanisms of some crustal earthquakes that occurred in the Pannonian depression (Arad \u2013 south Timisoara area), the Moesian platform and North Dobrogean Orogen. Rev. Roum. Geophys., 54, pp. 19\u201337.", "MICHAEL, A.J. (1984), Determination of stress from slip data: Faults and folds. J. Geophys. Res., 89, pp. 11.517\u201311.526.", "RADULIAN, M., B\u0102L\u0102, A., POPESCU, E., TOMA-D\u0102NIL\u0102, D. (2018), Earthquake mechanism and characterization of seismogenic zones in south-eastern part of Romania. Annals of Geophysics, 61(1), SE108.", "RADULIAN, M., B\u0102L\u0102, A., ARDELEANU, L., TOMA-D\u0102NIL\u0102, D., PETRESCU, L., POPESCU, E. (2019), Revised catalogue of earthquake mechanisms for the events occurred in Romania until the end of twentieth century: REFMC. Acta Geodaetica et Geophysica, 54, pp. 3\u201318.", "S\u0102NDULESCU, M. (1984), Geotectonics of Romania (in Romanian), Ed. Tehnic\u0103, pp. 334, Bucharest, Romania.", "VAVRY\u010cUK, V. (2015), Moment tensor decompositions revisited. Journal of Seismology, 19, 1, pp. 231\u2013252.", "ZOBACK, M.L. (1992), First and second order patterns of stress in the lithosphere: The World Stress Map Project. J. Geophys. Res., 97, pp. 11703\u201311728."]} Text Iceland DataCite Metadata Store (German National Library of Science and Technology) Fuchs ENVELOPE(-68.666,-68.666,-67.233,-67.233) Mueller ENVELOPE(55.533,55.533,-66.917,-66.917) Hippolyte ENVELOPE(-63.117,-63.117,-64.667,-64.667) Custodio ENVELOPE(-67.233,-67.233,-67.533,-67.533)

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