Abstract
The theme of this paper is the transformation of velocities from a GPS network into a surface strain rate field that illustrates recent and underlying movements within the tectonic system of Iceland. The surface strain rates presented are derived using GPS measurements at the base stations of the National Land Survey of Iceland reference network. The GPS observations are discussed, and the derived average velocity field for an 11-year period, from 1993 to 2004, is presented. The measurements at the westernmost and the easternmost points, which are located on the oldest parts of the country, i.e., the North America plate and the Eurasia plate, respectively, show the rigid movement of the two crustal plates. The average northwards velocity of the two plates is 25 mm/year, and the differential movement is 22 mm/year in the direction 281° from north. The definitions of strain rate tensor and vorticity tensor are outlined and applied in a numerical analysis to derive tensor strain rates from the GPS data. The strain rate tensor field is displayed on maps showing normal and shear strain rate fields, along with principal and dilatation rate fields, as well as the vorticity field. The derived tensor fields are discussed and interpreted in relation to the present-day view on the tectonism of Iceland and recent tectonic activity. The results indicate that most of the significant strain is concentrated on a tongue zone that goes from the North American plate into a slit in the Eurasian plate. The results clearly show the strained volcanic zone of Iceland and the rigid zones with zero strain on either side of it.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Akivis MA, Goldberg VV (2003) Tensor calculus with applications. World Scientific Publishing Company, Singapore, 380 pages
Alex R, Einarsson P, Heinert M, Niemeier W, Ritter B, Sigmundsson F, Willgalis S (1999) GPS-mefikampagne 1995 zur bestimmung von Deformationen der Erdkruste in Südwest-Island. Zeitschrift für Vermessungswesen 124(12):377–388
Ambraseys N, Sigbjörnsson R (2000) Re-appraisal of the seismicity of Iceland. Polytechnica – Engineering seismology, Earthquake Engineering Research Centre, University of Iceland, Selfoss, ISBN 9797-989-91-4X: 196 pages
Ambraseys NN, Smit P, Sigbjörnsson R, Suhadolc P, Margaris B (2002) Internet-site for European strong-motion data. European Commission, Research-Directorate General, Environment and Climate Programme, Brussels. URL: http://www.ised.hi.is Date visited: 30 April 2006
Ambraseys N, Douglas J, Sigbjörnsson R, Berge-Thierry C, Suhadolc P, Costa G, Smit P (2004) European strong-motion database, vol 2. Imperial College of Science, Technology and Medicine, London
Árnadóttir T, Thomley S, Pollitz FF, Darby DJ (1999) Spatial and temporal strain rate variations at the northern Hikurangi margin, New Zealand. J Geophys Res 104(B3):4931–4944
Árnadóttir T, Hreinsdóttir S, Gudmundsson G, Einarsson P, Heinert M, Volksen C (2001) Crustal deformation measured by GPS in the South Iceland Seismic Zone due to two large earthquakes in June 2000. Geophys Res Lett 28:4031–4033
Badawy A (2005) Present-day seismicity, stress field and crustal deformations of Egypt. J Seismol 9:267–276
Becker TW, Hardebeck JL, Anderson G (2005) Constraints on fault slip rates of the southern California plate boundary from GPS velocity and stress inversions. Geophys J Int 160(2):634–650
Bergerat F, Gudmundsson A, Angelier J, Rognvaldsson ST (1998) Seismotectonics of the central part of the South Iceland Seismic Zone. Tectonophysics 298(4):319–335
Camitz J, Sigmundsson F, Foulger G, Jahn C-H, Völksen C, Einarsson P (1995) Plate boundary deformation and continuing deflation of the Askja volcano, North Iceland, determined with GPS, 1987–1993. J Bull Volcanol 57(2)
D’Amico C, Albarello D, Sigbjörnsson R, Rupakhety R (2016) Seismic hazard assessment for Iceland in terms of macroseismic intensity using a site approach. Bull Earthq Eng 14(7):1945–1955
Fujii Y, Nakane K (1979) Anomalous crustal strain prior to the 1923 Kanto, Japan earthquake as deduced from analysis of old triangulation data. In: Wyss M (ed) Contributions to current research in geophysics 8: Earthquake prediction and seismicity patterns. Birkhauser Verlag, ISBN 3-7643-1122-3
Geirsson H, Árnadóttir T, Völksen C, Jiang W, Sturkell E, Villemin T, Einarsson P, Sigmundsson F, Stefánsson R (2006) Current plate movements across the Mid-Atlantic Ridge determined from 5 years of continuous GPS measurements in Iceland. J Geophys Res 111:B09407. doi:10.1029/2005JB003717
Gudmundsson A (2000) Dynamics of volcanic systems in Iceland: example of tectonism and volcanism at Juxtaposed hot spot and Mid-Ocean Ridge Systems. Annu Rev Earth Planet Sci 28:107–140
Gudmundsson A (2007) Infrastructure and evolution of ocean-ridge discontinuities in Iceland. J Geodyn 43:6–29
Kahle H-G, Cocard M, Peter Y, Geiger A, Reilinger R, Barka A, Veis G (2000) GPS-derived strain rate field within the boundary zones of the Eurasian, African, and Arabian plates. J Geophys Res 105(B10):23353–13370
LaFemina PC, Dixon TH, Malservisi R et al (2005) Geodetic GPS measurements in South Iceland: strain accumulation and partitioning in a propagating ridge system. J Geophys Res Solid Earth 110(B11.) Art. No. B11405
Lindman M (2001) Strain precursors for the June 2000 earthquakes, South Iceland, Luleå University of Technology, 302 CIV, ISSN 1402-1617, 98 pages
Lisowski M, Savage JC, Prescott WH (1991) The velocity field along the San Andreas fault in central and southern California. J Geophys Res 96(B5):8369–8389
Magnusson I Th, Thorbergsson G, Björnsson J Th (1997) GPS-mælingar í grunnstöðvaneti 1993 og ný viðmiðun ISN93 við landmælingar á Íslandi. National Land Survey of Iceland (www.lmi.is)
Murray MH, Lisowski M (2000) Strain accumulation along the Cascadia subduction zone. Geophys Res Lett 27(22):3631–3634
Murray F, Einarsson P, Bilham R, Sturkell E (1995) Rift-transform kinematics in South Iceland: deformation from Global Positioning system measurements, 1986 to 1992. J Geophys Res 100(B4):6235–6248
Nishimura S, Hashimoto M (2006) A model with rigid rotations and slip deficits for the GPS-derived velocity field in southwest Japan. Tectonophysics 421(3–4):187–207
Perlt J, Heinert M (2006) Kinematic model of the South Icelandic tectonic system. Geophys J Int 164:168–175
Pollitz FF, Vergnolle M (2006) Mechanical deformation model of the western United States instantaneous strain-rate field. Geophys J Int 167(1):421–444
Savage JC, Lisowski M, Prescott WH (1991) Strain accumulation in Western Washington. J Geophys Res 96(B9):14493–14507
Serpelloni E, Anzidei M, Baldi P et al (2005) Crustal velocity and strain-rate fields in Italy and surrounding regions: new results from the analysis of permanent and non-permanent GPS networks. Geophys J Int 161(3):861–880
Sigmundsson F (2006) Iceland geodynamics: crustal deformation and divergent plate tectonics. Springer, Berlin
Spain B (2003) Tensor calculus. Dover Publications
Stucchi M, Rovida A, Capera AG, Alexandre P, Camelbeeck T, Demircioglu MB, Gasperini P, Kouskouna V, Musson RM, Radulian M, Sesetyan K (2013) The SHARE European earthquake catalogue (SHEEC) 1000–1899. J Seismol 17(2):523–544
Tesauro M, Hollenstein C, Egli R et al (2005) Continuous GPS and broad-scale deformation across the Rhine Graben and the Alps. Int J Earth Sci 94(4):525–537
Thordarson T, Larsen G (2007) Volcanism in Iceland in historical time: volcano types, eruption styles and eruptive history. J Geodyn 43:118–152
Valsson G, Sigurdsson Th, Völksen C, Rennen M (2007) ISNET 2004 – Nidurstödur úr endurmælingum Grunnstödvanets Íslands, National Land Survey of Iceland (www.lmi.is)
Williams TB, Kelsey HM, Freymueller JT (2006) GPS-derived strain in northwestern California: termination of the San Andreas fault system and convergence of the Sierra Nevada-Great Valley block contribute to southern Cascadia forearc contraction. Tectonophysics 413(3–4):171–184
Acknowledgements
The present work was supported by Landsvirkjun (the National Power Company of Iceland) and the University of Iceland Research Fund.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2018 Springer International Publishing AG
About this chapter
Cite this chapter
Sigbjörnsson, R., Snæbjörnsson, J., Valsson, G., Sigurdsson, T., Rupakhety, R. (2018). Surface Strain Rate Tensor Field for Iceland Based on a GPS Network. In: Rupakhety, R., Ólafsson, S. (eds) Earthquake Engineering and Structural Dynamics in Memory of Ragnar Sigbjörnsson. ICESD 2017. Geotechnical, Geological and Earthquake Engineering, vol 44. Springer, Cham. https://doi.org/10.1007/978-3-319-62099-2_9
Download citation
DOI: https://doi.org/10.1007/978-3-319-62099-2_9
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-62098-5
Online ISBN: 978-3-319-62099-2
eBook Packages: Earth and Environmental ScienceEarth and Environmental Science (R0)