Shear-wave velocity structure of Australia from Rayleigh-wave analysis

The elastic structure beneath Australia is shown by means of S-velocity maps for depths ranging from zero to 400 km, determined by the regionalization and inversion of Rayleigh-wave dispersion. The traces of 233 earthquakes, occurred from 1990 to 2010, have been used to obtain Rayleigh-wave dispersi...

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Published in:Earth Sciences Research Journal
Main Author: Corchete, Víctor
Format: Article in Journal/Newspaper
Language:English
Published: Universidad Nacional de Colombia - Sede Bogotá - Facultad de Ciencias - Departamento de Geociencias 2014
Subjects:
Rayleigh wave
Shear wave
crust
upper mantle
Australia
Estructura de velocidad de onda S de Australia a partir del análisis de ondas Rayleigh
Antarc*
Antarctica
Online Access:https://revistas.unal.edu.co/index.php/esrj/article/view/41078
id ftuncolombiarev:oai:www.revistas.unal.edu.co:article/41078
record_format openpolar
institution Open Polar
collection Universidad Nacional de Colombia: Portal de Revistas UN
op_collection_id ftuncolombiarev
language English
topic Rayleigh wave
Shear wave
crust
upper mantle
Australia
Estructura de velocidad de onda S de Australia a partir del análisis de ondas Rayleigh
spellingShingle Rayleigh wave
Shear wave
crust
upper mantle
Australia
Estructura de velocidad de onda S de Australia a partir del análisis de ondas Rayleigh
Corchete, Víctor
Shear-wave velocity structure of Australia from Rayleigh-wave analysis
topic_facet Rayleigh wave
Shear wave
crust
upper mantle
Australia
Estructura de velocidad de onda S de Australia a partir del análisis de ondas Rayleigh
description The elastic structure beneath Australia is shown by means of S-velocity maps for depths ranging from zero to 400 km, determined by the regionalization and inversion of Rayleigh-wave dispersion. The traces of 233 earthquakes, occurred from 1990 to 2010, have been used to obtain Rayleigh-wave dispersion data. These earthquakes were registered by 65 seismic station located in Australia and the surrounding area. The dispersion curves were obtained for periods between 5 and 250 s, by digital filtering with a combination of MFT (Multiple Filter Technique) and TVF (Time Variable Filtering), filtering techniques. Later, all seismic events (and some stations) were grouped to obtain a dispersion curve for each source-station path. These dispersion curves were regionalized and inverted according to the generalized inversion theory, to obtain shear-wave velocity models for a rectangular grid of 2.5°×2.5° mesh size. The shear-velocity structure obtained through this procedure is shown in the S-velocity maps plotted for several depths. These results agree well with the geology and other geophysical results previously obtained. The obtained S-velocity models suggest the existence of lateral and vertical heterogeneity. The zones with consolidated and old structures present greater S-velocity values than those in the other zones, although this difference can be very little or negligible in some case. Nevertheless, in the depth range of 15 to 50 km, the different Moho depths present in the study area generate the principal variation of S-velocity. A similar behaviour is found for the depth range from 65 to 180 km, in which the lithosphere-asthenosphere boundary generates the principal variations of S-velocity. Finally, it should be highlighted a new and interesting feature was obtained in this study: the definition of the base of the asthenosphere, for depths ranging from 155 to 280 km, in Australia and the surrounding area. This feature is also present in the continents: South America, Antarctica and Africa, which were part of ...
format Article in Journal/Newspaper
author Corchete, Víctor
author_facet Corchete, Víctor
author_sort Corchete, Víctor
title Shear-wave velocity structure of Australia from Rayleigh-wave analysis
title_short Shear-wave velocity structure of Australia from Rayleigh-wave analysis
title_full Shear-wave velocity structure of Australia from Rayleigh-wave analysis
title_fullStr Shear-wave velocity structure of Australia from Rayleigh-wave analysis
title_full_unstemmed Shear-wave velocity structure of Australia from Rayleigh-wave analysis
title_sort shear-wave velocity structure of australia from rayleigh-wave analysis
publisher Universidad Nacional de Colombia - Sede Bogotá - Facultad de Ciencias - Departamento de Geociencias
publishDate 2014
url https://revistas.unal.edu.co/index.php/esrj/article/view/41078
genre Antarc*
Antarctica
genre_facet Antarc*
Antarctica
op_source Earth Sciences Research Journal; Vol. 18 No. 2 (2014); 87-98
Earth Sciences Research Journal; Vol. 18 Núm. 2 (2014); 87-98
2339-3459
1794-6190
op_relation https://revistas.unal.edu.co/index.php/esrj/article/view/41078/50515
https://revistas.unal.edu.co/index.php/esrj/article/view/41078/51720
Aitken A., 2011. Moho geometry gravity inversion experiment (MoGGIE): A refined model of the Australian Moho, and its tectonic and isostatic implications. Earth and Planetary Science Letters, 297, 71-83.
Aki K. and Richards P. G., 1980. Quantitative Seismology. Theory and methods. W. H. Freeman and Company, San Francisco.
Cara M., 1973. Filtering dispersed wavetrains. Geophysical Journal of the Royal Astronomic Society, 33, 65-80.
Corchete V., Chourak M. and Hussein H. M., 2007. Shear wave velocity structure of the Sinai Peninsula from Rayleigh wave analysis. Surveys in Geophysics, 28, 299-324.
Corchete V. and Chourak M., 2010. Shear-wave velocity structure of the western part of the Mediterranean Sea from Rayleigh-wave analysis. International Journal of Earth Sciences, 99, 955-972.
Corchete V., 2012. Shear-wave velocity structure of South America from Rayleigh-wave analysis. Terra Nova, 24, 87-104.
Corchete V., 2013a. Shear-wave velocity structure of Antarctica from Rayleigh-wave analysis. Tectonophysics, 583, 1-15.
Corchete V., 2013b. Shear-wave velocity structure of Africa from Rayleigh-wave analysis. International Journal of Earth Sciences, 102, 857-873.
Cull J. P., 1982. An appraisal of Australian heat flow data. Bureau of Mineral Resources Journal of Australian Geology and Geophysics, 7, 11-21.
Denham D. and Ellis R. M., 1986. Determination of earthquake focal mechanisms and crustal structure in eastern Australia using surface waves. Tectonophysics. 121, 109-123.
Dziewonski A., Bloch S., and Landisman M., 1969. A technique for the analysis of transient seismic signals. Bulletin of the Seismological Society of America, 59, No. 1, 427-444.
Dziewonski A. M. and Anderson D. L., 1981. Preliminary reference earth model. Physics of the Earth and Planetary Interiors, 25, 297-356.
Ellis R. M. and Denham D., 1985. Structure of the crust and upper mantle beneath Australia from Rayleigh- and Love-wave observations. Physics of the Earth and Planetary Interiors, 38, 224-234.
Fichtner A., Kennett B. L. N., Igel H. and Bunge H-P, 2009. Full seismic waveform tomography for upper-mantle structure in the Australasian region using adjoint methods. Geophysical Journal International, 179, 1703-1725.
Fishwick S., Kennett B. L. N. and Reading A. M., 2005. Contrasts in lithospheric structure within the Australian craton-insights from surface wave tomography. Earth and Planetary Science Letters, 231, 163-176.
Fishwick S., Heintz M., Kennett B. L. N., Reading A. M. and Yoshizawa K., 2008. Steps in lithospheric thickness within eastern Australia, evidence from surface wave tomography. Tectonics, 27, doi:10.1029/2007TC002116.
Fishwick S. and Reading A. M., 2008. Anomalous lithosphere beneath the Proterozoic of western and central Australia: A record of continental collision and intraplate deformation? Precambrian Research, 166, 111-121.
Fishwick S. and Rawlinson N., 2012. 3-D structure of the Australian lithosphere from evolving seismic datasets. Australian Journal of Earth Sciences, 59, 809-826.
Ford H. A., Fischer K. M., Abt D. L., Rychert C. A. and Elkins-Tanton L. T., 2010. The lithosphere-asthenosphere boundary and cratonic lithospheric layering beneath Australia from Sp wave imaging. Earth and Planetary Science Letters, 300, 299-310.
Johnson R.W. (ed.), 1989. Intraplate volcanism in Eastern Australia and New Zealand. Cambridge University Press, Melbourne.
Keilis-Borok V. I., 1989. Seismic surface waves in a laterally inhomogeneus Earth. Kluwer Academic Publishers, London, UK.
Kennett B. L. N., Salmon M., Saygin E. and AusMoho Working Group, 2011. AusMoho: the variation of Moho depth in Australia. Geophysical Journal International, doi:10.1111/j.1365-246X.2011.05194.x.
Kennett B. L. N. and Salmon M., 2012. AuSREM: Australian Seismological Reference Model. Australian Journal of Earth Sciences, accepted.
Okabe A., Kaneshima S., Kanjo K., Ohtaki T. and Purwana I., 2004. Surface wave tomography for southeastern Asia using IRIS-FARM and JISNET data. Physics of the Earth and Planetary Interiors, 146, 101-112.
Roult G. and Rouland D., 1994. Antarctica I: Deep structure investigations inferred from seismology; a review. Physics of the Earth and Planetary Interiors, 84, 15-32.
Saygin E. and Kennett B. L. N., 2012. Crustal structure of Australia from ambient seismic noise tomography. Journal of Geophysical Research, 117, B01304, doi:10.1029/2011JB008403.
Simons F. J., Zielhuis A. and van der Hilst R. D., 1999. The deep structure of the Australian continent from surface wave tomography. Lithos, 48, 17-43.
Zielhuis A. and van der Hilst, R. D., 1996. Upper-mantle shear velocity beneath eastern Australia from inversion of waveforms from SKIPPY portable arrays. Geophysical Journal International, 127, 1-16.
https://revistas.unal.edu.co/index.php/esrj/article/view/41078
op_rights Derechos de autor 2015 Earth Sciences Research Journal
op_doi https://doi.org/10.1029/2007TC002116
https://doi.org/10.1111/j.1365-246X.2011.05194.x
https://doi.org/10.1029/2011JB008403
container_title Earth Sciences Research Journal
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spelling ftuncolombiarev:oai:www.revistas.unal.edu.co:article/41078 2023-05-15T13:54:21+02:00 Shear-wave velocity structure of Australia from Rayleigh-wave analysis Corchete, Víctor 2014-07-01 application/pdf text/html https://revistas.unal.edu.co/index.php/esrj/article/view/41078 eng eng Universidad Nacional de Colombia - Sede Bogotá - Facultad de Ciencias - Departamento de Geociencias https://revistas.unal.edu.co/index.php/esrj/article/view/41078/50515 https://revistas.unal.edu.co/index.php/esrj/article/view/41078/51720 Aitken A., 2011. Moho geometry gravity inversion experiment (MoGGIE): A refined model of the Australian Moho, and its tectonic and isostatic implications. Earth and Planetary Science Letters, 297, 71-83. Aki K. and Richards P. G., 1980. Quantitative Seismology. Theory and methods. W. H. Freeman and Company, San Francisco. Cara M., 1973. Filtering dispersed wavetrains. Geophysical Journal of the Royal Astronomic Society, 33, 65-80. Corchete V., Chourak M. and Hussein H. M., 2007. Shear wave velocity structure of the Sinai Peninsula from Rayleigh wave analysis. Surveys in Geophysics, 28, 299-324. Corchete V. and Chourak M., 2010. Shear-wave velocity structure of the western part of the Mediterranean Sea from Rayleigh-wave analysis. International Journal of Earth Sciences, 99, 955-972. Corchete V., 2012. Shear-wave velocity structure of South America from Rayleigh-wave analysis. Terra Nova, 24, 87-104. Corchete V., 2013a. Shear-wave velocity structure of Antarctica from Rayleigh-wave analysis. Tectonophysics, 583, 1-15. Corchete V., 2013b. Shear-wave velocity structure of Africa from Rayleigh-wave analysis. International Journal of Earth Sciences, 102, 857-873. Cull J. P., 1982. An appraisal of Australian heat flow data. Bureau of Mineral Resources Journal of Australian Geology and Geophysics, 7, 11-21. Denham D. and Ellis R. M., 1986. Determination of earthquake focal mechanisms and crustal structure in eastern Australia using surface waves. Tectonophysics. 121, 109-123. Dziewonski A., Bloch S., and Landisman M., 1969. A technique for the analysis of transient seismic signals. Bulletin of the Seismological Society of America, 59, No. 1, 427-444. Dziewonski A. M. and Anderson D. L., 1981. Preliminary reference earth model. Physics of the Earth and Planetary Interiors, 25, 297-356. Ellis R. M. and Denham D., 1985. Structure of the crust and upper mantle beneath Australia from Rayleigh- and Love-wave observations. Physics of the Earth and Planetary Interiors, 38, 224-234. Fichtner A., Kennett B. L. N., Igel H. and Bunge H-P, 2009. Full seismic waveform tomography for upper-mantle structure in the Australasian region using adjoint methods. Geophysical Journal International, 179, 1703-1725. Fishwick S., Kennett B. L. N. and Reading A. M., 2005. Contrasts in lithospheric structure within the Australian craton-insights from surface wave tomography. Earth and Planetary Science Letters, 231, 163-176. Fishwick S., Heintz M., Kennett B. L. N., Reading A. M. and Yoshizawa K., 2008. Steps in lithospheric thickness within eastern Australia, evidence from surface wave tomography. Tectonics, 27, doi:10.1029/2007TC002116. Fishwick S. and Reading A. M., 2008. Anomalous lithosphere beneath the Proterozoic of western and central Australia: A record of continental collision and intraplate deformation? Precambrian Research, 166, 111-121. Fishwick S. and Rawlinson N., 2012. 3-D structure of the Australian lithosphere from evolving seismic datasets. Australian Journal of Earth Sciences, 59, 809-826. Ford H. A., Fischer K. M., Abt D. L., Rychert C. A. and Elkins-Tanton L. T., 2010. The lithosphere-asthenosphere boundary and cratonic lithospheric layering beneath Australia from Sp wave imaging. Earth and Planetary Science Letters, 300, 299-310. Johnson R.W. (ed.), 1989. Intraplate volcanism in Eastern Australia and New Zealand. Cambridge University Press, Melbourne. Keilis-Borok V. I., 1989. Seismic surface waves in a laterally inhomogeneus Earth. Kluwer Academic Publishers, London, UK. Kennett B. L. N., Salmon M., Saygin E. and AusMoho Working Group, 2011. AusMoho: the variation of Moho depth in Australia. Geophysical Journal International, doi:10.1111/j.1365-246X.2011.05194.x. Kennett B. L. N. and Salmon M., 2012. AuSREM: Australian Seismological Reference Model. Australian Journal of Earth Sciences, accepted. Okabe A., Kaneshima S., Kanjo K., Ohtaki T. and Purwana I., 2004. Surface wave tomography for southeastern Asia using IRIS-FARM and JISNET data. Physics of the Earth and Planetary Interiors, 146, 101-112. Roult G. and Rouland D., 1994. Antarctica I: Deep structure investigations inferred from seismology; a review. Physics of the Earth and Planetary Interiors, 84, 15-32. Saygin E. and Kennett B. L. N., 2012. Crustal structure of Australia from ambient seismic noise tomography. Journal of Geophysical Research, 117, B01304, doi:10.1029/2011JB008403. Simons F. J., Zielhuis A. and van der Hilst R. D., 1999. The deep structure of the Australian continent from surface wave tomography. Lithos, 48, 17-43. Zielhuis A. and van der Hilst, R. D., 1996. Upper-mantle shear velocity beneath eastern Australia from inversion of waveforms from SKIPPY portable arrays. Geophysical Journal International, 127, 1-16. https://revistas.unal.edu.co/index.php/esrj/article/view/41078 Derechos de autor 2015 Earth Sciences Research Journal Earth Sciences Research Journal; Vol. 18 No. 2 (2014); 87-98 Earth Sciences Research Journal; Vol. 18 Núm. 2 (2014); 87-98 2339-3459 1794-6190 Rayleigh wave Shear wave crust upper mantle Australia Estructura de velocidad de onda S de Australia a partir del análisis de ondas Rayleigh info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion 2014 ftuncolombiarev https://doi.org/10.1029/2007TC002116 https://doi.org/10.1111/j.1365-246X.2011.05194.x https://doi.org/10.1029/2011JB008403 2022-12-14T08:57:54Z The elastic structure beneath Australia is shown by means of S-velocity maps for depths ranging from zero to 400 km, determined by the regionalization and inversion of Rayleigh-wave dispersion. The traces of 233 earthquakes, occurred from 1990 to 2010, have been used to obtain Rayleigh-wave dispersion data. These earthquakes were registered by 65 seismic station located in Australia and the surrounding area. The dispersion curves were obtained for periods between 5 and 250 s, by digital filtering with a combination of MFT (Multiple Filter Technique) and TVF (Time Variable Filtering), filtering techniques. Later, all seismic events (and some stations) were grouped to obtain a dispersion curve for each source-station path. These dispersion curves were regionalized and inverted according to the generalized inversion theory, to obtain shear-wave velocity models for a rectangular grid of 2.5°×2.5° mesh size. The shear-velocity structure obtained through this procedure is shown in the S-velocity maps plotted for several depths. These results agree well with the geology and other geophysical results previously obtained. The obtained S-velocity models suggest the existence of lateral and vertical heterogeneity. The zones with consolidated and old structures present greater S-velocity values than those in the other zones, although this difference can be very little or negligible in some case. Nevertheless, in the depth range of 15 to 50 km, the different Moho depths present in the study area generate the principal variation of S-velocity. A similar behaviour is found for the depth range from 65 to 180 km, in which the lithosphere-asthenosphere boundary generates the principal variations of S-velocity. Finally, it should be highlighted a new and interesting feature was obtained in this study: the definition of the base of the asthenosphere, for depths ranging from 155 to 280 km, in Australia and the surrounding area. This feature is also present in the continents: South America, Antarctica and Africa, which were part of ... Article in Journal/Newspaper Antarc* Antarctica Universidad Nacional de Colombia: Portal de Revistas UN Earth Sciences Research Journal 18 2 87 98

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