Estimation of slip distribution for the Mw7.8 Kunlunshan earthquake by coseismic displacements

doi:10.7523/j.issn.2095-6134.2015.05.011

Abstract

Abstract:

The M_w7.8 Kunlunshan earthquake of November 14,2001, which ruptured over a total distance of about 400 km, was characterized by a 350-km-long main fault with an east-ward-propagating pulse of left-lateral slip. The field observations of coseismic displacement along the main fault provide us a good opportunity to study the earthquake source mechanism and fault geometry inside the earth. In this paper, based on Freund's III-dislocation model and constrained by two groups of surface rupture data from field investigation and geodetic measurement, we invert the slip distribution, the variation of static stress drop on the fault surface, and the fault width extending at depth along the fault strike-slip direction. The pattern of slip distribution on the fault surface deduced from the III-dislocation model is very similar to the result of the finite-fault solution based on the teleseismic body-wave inversion, showing that both slip distributions appear intensively heterogeneous in the special domain. The fault rupture width is much less than 20 km. These results also imply that the coseismic displacement along the fault strike direction on the earth surface is proportional to the fault width. In addition we also calculate the static stress change on the fault based on the III-dislocation model and slip distribution by teleseismic inversion. The analytical and numerical results show that they have high-level consistency.

Key words: Kunlunshan earthquake, surface coseismic displacement, slip model, stress change

CLC Number:

P315

MI Qi, LI Yanheng, SHEN Wenhao, SHI Baoping. Estimation of slip distribution for the M_w7.8 Kunlunshan earthquake by coseismic displacements[J]. , 2015, 32(5): 652-660.

References

[1] Xu X, Chen W, Ma W, et al. Surface rupture of the Kunlunshan earthquake (Ms 8.1), northern Tibetan plateau, China [J]. Seismology Research Letter, 2002, 73:884-892.

[2] P J, Schwartz D P, Dawson T E, et al. Surface rupture of the 2002 Denali Fault, Alaska, earthquake and comparison with other strike-slip ruptures[J]. Earthquake Spectral, 2004, 20: 565-578.

[3] Ozaxar A A, Beck S L. The 2002 Denali fault and 2001 Kunlun fault earthquakes: complex rupture processes of two large strike-slip events[J]. Bulletin of the Seismological Society of America, 2004, 94:S278-S292.

[4] Antolik M, Abercrombie R E, Ekstrom E. The 14 November 2001 Kokoxili (Kunlunshan), Tibet, earthquake: rupture transfer through a large extensional step-over[J]. Bulletin of the Seismological Society of America, 2004,94: 1173-1194.

[5] Xu L S, Chen Y T. Temporal and spatial rupture process of the great Kunlun Mountain Pass earthquake of Nov.14, 2001, from GDSN long period waveform data [J]. Science in China, 2004,34 (3):256-264.

[6] 周仕勇,许忠淮,陈晓非.伽师强震群震源特征及震源机制力学成因分析[J].地球物理学报, 2001, 44(5):654-662.

[7] Scholz C. The mechanics of earthquakes and faulting[M]. New York: Cambridge U Press, 1990.

[8] Kanamori H, Anderson D L. Theoretical basis of some empirical relations in seismology[J]. Bulletin of the Seismological Society of America, 1975, 65:1073-1095.

[9] Scholz C. Scaling laws for large earthquakes: consequences for physical models[J]. Bulletin of the Seismological Society of America, 1982, 72:1-14.

[10] Romanowicz B. Strike-slip earthquakes on quasi-vertical transcurrent faults: inferences for general scaling relations[J]. Geophysical Research Letters, 1992, 19:481-484.

[11] Bodin P, Brune J N. On the scaling of slip with rupture length for shallow strike-slip earthquakes: quasi-static models and dynamic rupture propagation[J]. Bulletin of the Seismological Society of America, 1996, 86:1292-1299.

[12] Shaw B E, Scholz C H. Slip-length scaling in large earthquakes: observations and theory and implications for earthquake physics[J]. Geophysical Research Letters, 2001, 28:2991-2994.

[13] Zeng L Z, Heaton T, Christopher D. The effect of slip variability on earthquake slip-length scaling[J]. Geophysical Journal International, 2005, 162(3): 841-849.

[14] King C P G, Wensnosky S G. Scaling of fault parameters for continental strike-slip earthquakes[J]. Bulletin of the Seismological Society of America, 2007, 97:1833-1840.

[15] Barnett D M, Freund L B. An estimate of strike-slip fault friction stress and fault depth from surface displacement data[J]. Bulletin of the Seismological Society of America, 1975, 65:1259-1266.

[16] 陈杰,陈宇坤,丁国瑜,等.2001年昆仑山口西8.1级地震地表破裂带[J].第四纪研究,2003, 23(6):629-639.

[17] Klinger Y, Xu X W, Tapponnier P, et al. High-resolution satellite imagery mapping of the surface rupture and slip distribution of the Ms7.8, 14 Novermber 2001 Kokoxili Earthquake, Kunlun Fault, Northern Tibet, China[J]. Bulletin of the Seismological Society of America, 2005, 95(5):1970.

[18] Hirth J P, Lothe J. Theory of dislocations[M]. New York: McGraw-Hill,1968.

[19] Weertman J. Relationship between displacements on a free surface and the stress on a fault[J]. Bulletin of the Seismological Society of America, 1965, 55: 945-953.

[20] Das S. The need to study speed[J]. Science, 2007, 317(17): 905.

[21] Cotton F, Archuleta R, Causse M. What is sigma of the stress drop?[J]. Seismological Research Letters, 2013,84(1):42-48.

[22] Toda S, Stein R S, Beroza G C, et al. Aftershocks halted by static stress shadows[J]. Nature, 2012,5:410-413.

[23] Andrew D J. A stochastic fault model: 1. Static case[J]. Journal of Geophysical Research, 1980, 85:3867-3877.

[24] Paul S. Earthquake and volcano deformation[M]. Princeton University Press, Princeton and Oxford. 2010.

[25] Okada Y. Internal deformation due to shear and tensile faults in a half-space[J]. Bulletin of the Seismological Society of America,1992,82:1018-1040.

Estimation of slip distribution for the M_w7.8 Kunlunshan earthquake by coseismic displacements

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