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First geodetic observations of a deep earthquake: The 2013 Sea of Okhotsk M w 8.3, 611 km‐deep, event
Author(s) -
Steblov Grigory M.,
Ekström Göran,
Kogan Mikhail G.,
Freymueller Jeffrey T.,
Titkov Nikolay N.,
Vasilenko Nikolay F.,
Nettles Meredith,
Gabsatarov Yury V.,
Prytkov Alexandr S.,
Frolov Dmitry I.,
Kondratyev Mikhail N.
Publication year - 2014
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1002/2014gl060003
Subject(s) - geology , hypocenter , seismology , geodetic datum , seismic moment , geodesy , global positioning system , moment tensor , slip (aerodynamics) , deep focus earthquake , shear (geology) , slab , moment magnitude scale , subduction , fault (geology) , deformation (meteorology) , induced seismicity , geophysics , tectonics , geometry , physics , petrology , telecommunications , oceanography , mathematics , scaling , computer science , thermodynamics
We analyze the first ever GPS observations of static surface deformation from a deep earthquake: the 24 May 2013 M w 8.3 Sea of Okhotsk, 611 km‐deep, event. Previous studies of deep earthquake sources relied on seismology and might have missed evidence for slow slip in the rupture. We observed coseismic static offsets on a GPS network of 20 stations over the Sea of Okhotsk region. The offsets were inverted for the best fitting double‐couple source model assuming a layered spherical Earth. The seismic moment calculated from static offsets is only 7% larger than the seismological estimate from Global Centroid Moment Tensor (GCMT). Thus, GPS observations confirm shear faulting as the source model, with no significant slow‐slip component. The relative locations of the U.S. Geological Survey hypocenter, GCMT centroid, and the fault from GPS indicate slip extending for tens of kilometers across most of the slab thickness.