Coseismic Deformation Field of theMw 7.3 12 November 2017 Sarpol-e Zahab (Iran) Earthquake: A Decoupling Horizon in the Northern Zagros Mountains Inferred from InSAR Observations

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Sanaz Vajedian
  • Mahdi Motagh
  • Zahra Mousavi
  • Khalil Motaghi
  • Eric J. Fielding
  • Bahman Akbari
  • Hans-Ulrich Wetzel
  • Aliakbar Darabi

Research Organisations

External Research Organisations

  • Helmholtz Centre Potsdam - German Research Centre for Geosciences (GFZ)
  • Institute for Advanced Studies in Basic Sciences, Zanjan
  • California Institute of Caltech (Caltech)
  • Forest, Range and Watershed Management Organization of Iran
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Details

Original languageEnglish
Article number1589
JournalRemote Sensing
Volume10
Issue number10
Early online date3 Oct 2018
Publication statusE-pub ahead of print - 3 Oct 2018

Abstract

The study of crustal deformation fields caused by earthquakes is important for a better understanding of seismic hazard and growth of geological structures in tectonically active areas. In this study, we present, using interferometric measurements constructed from Sentinel-1 Terrain Observation with Progressive Scan (TOPS) data and ALOS-2 ScanSAR, coseismic deformation and source model of the Mw 7.3, 12 November 2017 earthquake that hit northwest of the Zagros Mountains in the region between Iran-Iraq border. This was one of the strongest seismic events to hit this region in the past century, and it resulted in an uplift area of about 3500 km2 between the High Zagros Fault (HZF) and Mountain Front Fault (MFF) with a maximum amount of 70 cm south of Miringe fault. A subsidence over an area of 1200 km2 with a maximum amount of 35 cm occurred near Vanisar village at the hanging wall of the HZF. Bayesian inversion of interferometric synthetic aperture radar (InSAR) observations suggests a source model at a depth between 14 and 20 km that is consistent with the existence of a decoupling horizon southwest edge of the northern portion of the Zagros Mountains near the MFF. Moreover, we present evidence for a number of coseismically induced rockslides and landslides, the majority of them which occurred along or close to pre-existing faults, causing decorrelation in differential interferograms. Exploiting the offset-tracking technique, we estimated surface motion by up to 34 and 10 m in horizontal and vertical directions, respectively, due to lateral spreading on a big coseismic-induced landslide near Mela-Kabod. Field observations also revealed several zones of en echelon fractures and crack zones developed along a pre-existing fault passing through Qasr-e Shirin City, which exhibited secondary surface slip by up to 14 cm along its strike.

Keywords

    Burst overlap interferometry, InSAR geodesy, Landslide, Offset tracking, Sarpol-e Zahab earthquake, Triggered slip

ASJC Scopus subject areas

Cite this

Coseismic Deformation Field of theMw 7.3 12 November 2017 Sarpol-e Zahab (Iran) Earthquake: A Decoupling Horizon in the Northern Zagros Mountains Inferred from InSAR Observations. / Vajedian, Sanaz; Motagh, Mahdi; Mousavi, Zahra et al.
In: Remote Sensing, Vol. 10, No. 10, 1589, 03.10.2018.

Research output: Contribution to journalArticleResearchpeer review

Vajedian, S., Motagh, M., Mousavi, Z., Motaghi, K., Fielding, E. J., Akbari, B., Wetzel, H.-U., & Darabi, A. (2018). Coseismic Deformation Field of theMw 7.3 12 November 2017 Sarpol-e Zahab (Iran) Earthquake: A Decoupling Horizon in the Northern Zagros Mountains Inferred from InSAR Observations. Remote Sensing, 10(10), Article 1589. Advance online publication. https://doi.org/10.3390/rs10101589, https://doi.org/10.15488/4064
Vajedian S, Motagh M, Mousavi Z, Motaghi K, Fielding EJ, Akbari B et al. Coseismic Deformation Field of theMw 7.3 12 November 2017 Sarpol-e Zahab (Iran) Earthquake: A Decoupling Horizon in the Northern Zagros Mountains Inferred from InSAR Observations. Remote Sensing. 2018 Oct 3;10(10):1589. Epub 2018 Oct 3. doi: 10.3390/rs10101589, 10.15488/4064
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title = "Coseismic Deformation Field of theMw 7.3 12 November 2017 Sarpol-e Zahab (Iran) Earthquake: A Decoupling Horizon in the Northern Zagros Mountains Inferred from InSAR Observations",
abstract = "The study of crustal deformation fields caused by earthquakes is important for a better understanding of seismic hazard and growth of geological structures in tectonically active areas. In this study, we present, using interferometric measurements constructed from Sentinel-1 Terrain Observation with Progressive Scan (TOPS) data and ALOS-2 ScanSAR, coseismic deformation and source model of the Mw 7.3, 12 November 2017 earthquake that hit northwest of the Zagros Mountains in the region between Iran-Iraq border. This was one of the strongest seismic events to hit this region in the past century, and it resulted in an uplift area of about 3500 km2 between the High Zagros Fault (HZF) and Mountain Front Fault (MFF) with a maximum amount of 70 cm south of Miringe fault. A subsidence over an area of 1200 km2 with a maximum amount of 35 cm occurred near Vanisar village at the hanging wall of the HZF. Bayesian inversion of interferometric synthetic aperture radar (InSAR) observations suggests a source model at a depth between 14 and 20 km that is consistent with the existence of a decoupling horizon southwest edge of the northern portion of the Zagros Mountains near the MFF. Moreover, we present evidence for a number of coseismically induced rockslides and landslides, the majority of them which occurred along or close to pre-existing faults, causing decorrelation in differential interferograms. Exploiting the offset-tracking technique, we estimated surface motion by up to 34 and 10 m in horizontal and vertical directions, respectively, due to lateral spreading on a big coseismic-induced landslide near Mela-Kabod. Field observations also revealed several zones of en echelon fractures and crack zones developed along a pre-existing fault passing through Qasr-e Shirin City, which exhibited secondary surface slip by up to 14 cm along its strike.",
keywords = "Burst overlap interferometry, InSAR geodesy, Landslide, Offset tracking, Sarpol-e Zahab earthquake, Triggered slip",
author = "Sanaz Vajedian and Mahdi Motagh and Zahra Mousavi and Khalil Motaghi and Fielding, {Eric J.} and Bahman Akbari and Hans-Ulrich Wetzel and Aliakbar Darabi",
note = "Funding information: Acknowledgments: The Sentinel InSAR original data used in this paper are freely available and provided by Copernicus and ESA. Original ALOS-2 data are copyrighted by the Japanese Aerospace Exploration Agency (JAXA) and were provided under JAXA ALOS RA-4 project PI1162. Part of this research was supported by the NASA Earth Surface and Interior focus area and performed at the Jet Propulsion Laboratory, California Institute of Technology. Maps were prepared using the Generic Mapping Tools (GMT) , SOEST, University of Hawaii, USA [57]. We appreciate Mahmud Haghshenas-Haghighi for sharing his ALOS-2 results, Sigrid Roessner from GFZ for her assistance in the field, and Esmaeil Shabanian from IASBS for his constructive comments on the geodynamic model. We thank three anonymous reviewers for their careful reading of our manuscript and their insightful comments and suggestions. The Sentinel InSAR original data used in this paper are freely available and provided by Copernicus and ESA. Original ALOS-2 data are copyrighted by the Japanese Aerospace Exploration Agency (JAXA) and were provided under JAXA ALOS RA-4 project PI1162. Part of this research was supported by the NASA Earth Surface and Interior focus area and performed at the Jet Propulsion Laboratory, California Institute of Technology. Maps were prepared using the Generic Mapping Tools (GMT), SOEST, University of Hawaii, USA [57]. We appreciate Mahmud Haghshenas-Haghighi for sharing his ALOS-2 results, Sigrid Roessner from GFZ for her assistance in the field, and Esmaeil Shabanian from IASBS for his constructive comments on the geodynamic model. We thank three anonymous reviewers for their careful reading of our manuscript and their insightful comments and suggestions. This research received no external funding.",
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T1 - Coseismic Deformation Field of theMw 7.3 12 November 2017 Sarpol-e Zahab (Iran) Earthquake: A Decoupling Horizon in the Northern Zagros Mountains Inferred from InSAR Observations

AU - Vajedian, Sanaz

AU - Motagh, Mahdi

AU - Mousavi, Zahra

AU - Motaghi, Khalil

AU - Fielding, Eric J.

AU - Akbari, Bahman

AU - Wetzel, Hans-Ulrich

AU - Darabi, Aliakbar

N1 - Funding information: Acknowledgments: The Sentinel InSAR original data used in this paper are freely available and provided by Copernicus and ESA. Original ALOS-2 data are copyrighted by the Japanese Aerospace Exploration Agency (JAXA) and were provided under JAXA ALOS RA-4 project PI1162. Part of this research was supported by the NASA Earth Surface and Interior focus area and performed at the Jet Propulsion Laboratory, California Institute of Technology. Maps were prepared using the Generic Mapping Tools (GMT) , SOEST, University of Hawaii, USA [57]. We appreciate Mahmud Haghshenas-Haghighi for sharing his ALOS-2 results, Sigrid Roessner from GFZ for her assistance in the field, and Esmaeil Shabanian from IASBS for his constructive comments on the geodynamic model. We thank three anonymous reviewers for their careful reading of our manuscript and their insightful comments and suggestions. The Sentinel InSAR original data used in this paper are freely available and provided by Copernicus and ESA. Original ALOS-2 data are copyrighted by the Japanese Aerospace Exploration Agency (JAXA) and were provided under JAXA ALOS RA-4 project PI1162. Part of this research was supported by the NASA Earth Surface and Interior focus area and performed at the Jet Propulsion Laboratory, California Institute of Technology. Maps were prepared using the Generic Mapping Tools (GMT), SOEST, University of Hawaii, USA [57]. We appreciate Mahmud Haghshenas-Haghighi for sharing his ALOS-2 results, Sigrid Roessner from GFZ for her assistance in the field, and Esmaeil Shabanian from IASBS for his constructive comments on the geodynamic model. We thank three anonymous reviewers for their careful reading of our manuscript and their insightful comments and suggestions. This research received no external funding.

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N2 - The study of crustal deformation fields caused by earthquakes is important for a better understanding of seismic hazard and growth of geological structures in tectonically active areas. In this study, we present, using interferometric measurements constructed from Sentinel-1 Terrain Observation with Progressive Scan (TOPS) data and ALOS-2 ScanSAR, coseismic deformation and source model of the Mw 7.3, 12 November 2017 earthquake that hit northwest of the Zagros Mountains in the region between Iran-Iraq border. This was one of the strongest seismic events to hit this region in the past century, and it resulted in an uplift area of about 3500 km2 between the High Zagros Fault (HZF) and Mountain Front Fault (MFF) with a maximum amount of 70 cm south of Miringe fault. A subsidence over an area of 1200 km2 with a maximum amount of 35 cm occurred near Vanisar village at the hanging wall of the HZF. Bayesian inversion of interferometric synthetic aperture radar (InSAR) observations suggests a source model at a depth between 14 and 20 km that is consistent with the existence of a decoupling horizon southwest edge of the northern portion of the Zagros Mountains near the MFF. Moreover, we present evidence for a number of coseismically induced rockslides and landslides, the majority of them which occurred along or close to pre-existing faults, causing decorrelation in differential interferograms. Exploiting the offset-tracking technique, we estimated surface motion by up to 34 and 10 m in horizontal and vertical directions, respectively, due to lateral spreading on a big coseismic-induced landslide near Mela-Kabod. Field observations also revealed several zones of en echelon fractures and crack zones developed along a pre-existing fault passing through Qasr-e Shirin City, which exhibited secondary surface slip by up to 14 cm along its strike.

AB - The study of crustal deformation fields caused by earthquakes is important for a better understanding of seismic hazard and growth of geological structures in tectonically active areas. In this study, we present, using interferometric measurements constructed from Sentinel-1 Terrain Observation with Progressive Scan (TOPS) data and ALOS-2 ScanSAR, coseismic deformation and source model of the Mw 7.3, 12 November 2017 earthquake that hit northwest of the Zagros Mountains in the region between Iran-Iraq border. This was one of the strongest seismic events to hit this region in the past century, and it resulted in an uplift area of about 3500 km2 between the High Zagros Fault (HZF) and Mountain Front Fault (MFF) with a maximum amount of 70 cm south of Miringe fault. A subsidence over an area of 1200 km2 with a maximum amount of 35 cm occurred near Vanisar village at the hanging wall of the HZF. Bayesian inversion of interferometric synthetic aperture radar (InSAR) observations suggests a source model at a depth between 14 and 20 km that is consistent with the existence of a decoupling horizon southwest edge of the northern portion of the Zagros Mountains near the MFF. Moreover, we present evidence for a number of coseismically induced rockslides and landslides, the majority of them which occurred along or close to pre-existing faults, causing decorrelation in differential interferograms. Exploiting the offset-tracking technique, we estimated surface motion by up to 34 and 10 m in horizontal and vertical directions, respectively, due to lateral spreading on a big coseismic-induced landslide near Mela-Kabod. Field observations also revealed several zones of en echelon fractures and crack zones developed along a pre-existing fault passing through Qasr-e Shirin City, which exhibited secondary surface slip by up to 14 cm along its strike.

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