TY - JOUR
T1 - The 2011 Mw 9.0 off the Pacific coast of Tohoku Earthquake
T2 - Comparison of deep-water tsunami signals with finite-fault rupture model predictions
AU - Lay, Thorne
AU - Yamazaki, Yoshiki
AU - Ammon, Charles J.
AU - Cheung, Kwok Fai
AU - Kanamori, Hiroo
N1 - Funding Information:
Acknowledgments. This work made use of GMT, SAC and Mat-lab software. The IRIS DMS data center was used to access the seismic data. Continuous GPS data processed with 30 s sampling were provided by the ARIA team at JPL and Caltech courtesy of Susan Owen. The recorded DART buoy data were obtained from the NOAA National Data Buoy Center. We thank Y. Tanioka and S. Lorito for helpful reviews of the manuscript. This work was supported by NSF grant EAR0635570 and USGS Award Number 05HQGR0174.
PY - 2011
Y1 - 2011
N2 - Finite-source rupture models for the great 11 March 2011 off the Pacific coast of Tohoku (Mw 9.0) Earthquake obtained by inversions of seismic waves and geodetic observations are used to reconstruct deep-water tsunami recordings from DART buoys near Japan. One model is from least-squares inversion of teleseismic P waves, and another from iterative least-squares search-based joint inversion of teleseismic P waves, short-arc Rayleigh wave relative source time functions, and high-rate GPS observations from northern Honshu. These rupture model inversions impose similar kinematic constraints on the rupture growth, and both have concentrations of slip of up to 42 m up-dip from the hypocenter, with substantial slip extending to the trench. Tsunami surface elevations were computed using the model NEOWAVE, which includes a vertical momentum equation and a non-hydrostatic pressure term in the nonlinear shallow-water equations to account for the time-history of seafloor deformation and propagation of weakly dispersive tsunami waves. Kinematic seafloor deformations were computed using the Okada solutions for the rupture models. Good matches to the tsunami arrival times and waveforms are achieved for the DART recordings for models with slip extending all the way to the trench, whereas shifting fault slip toward the coast degrades the predictions.
AB - Finite-source rupture models for the great 11 March 2011 off the Pacific coast of Tohoku (Mw 9.0) Earthquake obtained by inversions of seismic waves and geodetic observations are used to reconstruct deep-water tsunami recordings from DART buoys near Japan. One model is from least-squares inversion of teleseismic P waves, and another from iterative least-squares search-based joint inversion of teleseismic P waves, short-arc Rayleigh wave relative source time functions, and high-rate GPS observations from northern Honshu. These rupture model inversions impose similar kinematic constraints on the rupture growth, and both have concentrations of slip of up to 42 m up-dip from the hypocenter, with substantial slip extending to the trench. Tsunami surface elevations were computed using the model NEOWAVE, which includes a vertical momentum equation and a non-hydrostatic pressure term in the nonlinear shallow-water equations to account for the time-history of seafloor deformation and propagation of weakly dispersive tsunami waves. Kinematic seafloor deformations were computed using the Okada solutions for the rupture models. Good matches to the tsunami arrival times and waveforms are achieved for the DART recordings for models with slip extending all the way to the trench, whereas shifting fault slip toward the coast degrades the predictions.
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U2 - 10.5047/eps.2011.05.030
DO - 10.5047/eps.2011.05.030
M3 - Article
AN - SCOPUS:80054774912
SN - 1343-8832
VL - 63
SP - 797
EP - 801
JO - Earth, Planets and Space
JF - Earth, Planets and Space
IS - 7
ER -