Shear instability in a viscoelastic material as the cause of deep focus earthquakes

Ogawa, Masaki

doi:10.1029/jb092ib13p13801

Cited by 232 publications

(198 citation statements)

References 28 publications

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“…A number of processes have been suggested for causing local weakening. These include shear instabilities (Ogawa, 1987;Kelemen and Hirth, 2007), thermal runaways (John et al, 2010), and local weakening and embrittlement of the crust due to dehydration (e.g., Raleigh and Paterson, 1965;Kirby et al, 1996;Seno and Yamanaka, 1996;Hacker et al, 2003;Yamasaki and Seno, 2003). Possible consequences of dehydration include stress changes to the change in volume of the oceanic crust , pore pressure changes (Wong et al, 1997) or just the release and transport of water (e.g., Jung et al, 2004;John and Schenk, 2006).…”

Section: Discussionmentioning

confidence: 99%

Thermal structure and intermediate-depth seismicity in the Tohoku-Hokkaido subduction zones

2012

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Abstract. The cause of intermediate-depth (> 40 km) seismicity in subduction zones is not well understood. The viability of proposed mechanisms, which include dehydration embrittlement, shear instabilities and the presence of fluids in general, depends significantly on local conditions, including pressure, temperature and composition. The wellinstrumented and well-studied subduction zone below Northern Japan (Tohoku and Hokkaido) provides an excellent testing ground to study the conditions under which intermediatedepth seismicity occurs. This study combines new finite element models that predict the dynamics and thermal structure of the Japan subduction system with a high-precision hypocenter data base. The upper plane of seismicity is principally contained in the crustal portion of the subducting slab and appears to thin and deepen within the crust at depths > 80 km. The disappearance of seismicity overlaps in most of the region with the predicted phase change of blueschist to hydrous eclogite, which forms a major dehydration front in the crust. The correlation between the thermally predicted blueschist-out boundary and the disappearance of seismicity breaks down in the transition from the northern Japan to Kurile arc below western Hokkaido. Adjusted models that take into account the seismically imaged modified upper mantle structure in this region fail to adequately recover the correlation that is seen below Tohoku and eastern Hokkaido. We conclude that the thermal structure below Western Hokkaido is significantly affected by timedependent, 3-D dynamics of the slab. This study generally supports the role of fluids in the generation of intermediatedepth seismicity.

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Section: Discussionmentioning

confidence: 99%

Thermal structure and intermediate-depth seismicity in the Tohoku-Hokkaido subduction zones

2012

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“…Several proposed mechanisms for deep earthquakes, including plastic shear instabilities [Ogawa, 1987] and frictional melting [Kanarnori et al, 1997], would be expected to show a strong temperature dependence. The form of this temperature dependence may provide one of the few observational constraints on the mechanism of deep earthquakes.…”

Section: Implications For the Mechanism Of Deep Earthquakesmentioning

confidence: 99%

Source and aftershock properties of the 1996 Flores Sea Deep Earthquake

Wiens¹

1998

Geophysical Research Letters

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Abstract. The June 17, 1996 (M w 7.8) Flores Sea event is one of the largest deep earthquakes, and also produced an energetic aftershock sequence, allowing study of the spatial relationships between moment release, aftershock occurrence, and slab geometry. The locations of the mainshock, rupture sub-events, aftershocks, and background slab seismicity are determined using a relative location algorithm. The event occurred at the edge of a 150 km wide aseismic region that represents a tear in the lowermost part of the Indonesian slab. The aftershocks define a 90 km long region parallel to slab strike. Two other aftershocks locate 10-25 km outside the previously active slab.The mainshock propagated about 75 km eastward along an E-W striking, southward dipping plane, with a rupture velocity of 3.5 km/s. There was a substantial change in focal mechanism during the rupture, with the fault plane strike changing by about 25 ø . Overall, the Flores Sea deep earthquake shows numerous large aftershocks, and a moderate rupture velocity (3.5 km/s) and stress drop (-7-20 MPa.) These characteristics are similar to the 1994 Tonga deep earthquake, but different from the 1994 Bolivia event, suggesting they may be typical of large deep earthquakes in colder slabs. Systematic differences in rupture parameters for deep earthquakes in warm and cold slabs suggest that the rupture mechanism is highly sensitive to temperature.

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“…In this paper we wish to address the role played in the plate-breaking problem by lithospheric elasticity coupled to a temperature-dependent visco-plastic rheology. Previous work based on a one-dimensional time-dependent model [Ogawa, 1987] has demonstrated that visco-elasticity could be a very efficient mechanism for transferring rather rapidly potential energy from elasticity into shear heating, which might cause deep-focus earthquakes. The conversion of elastic strain energy to shear heating can potentially be an attractive mechanism for facilitating localized deformation in the lithosphere.…”

Section: Introductionmentioning

confidence: 99%

Rapid conversion of elastic energy into plastic shear heating during incipient necking of the lithosphere

Regenauer‐Lieb

Yuen

1998

Geophysical Research Letters

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Abstract. An important and novel mechanism for ductile failure of the lithosphere is identified here, which is intrinsic to the thermal-mechanical feedback in a temperature dependent plastic body with coupled elastic fields. Both a temperaturedependent power-law visco-elasto-plastic theology and a temperature-dependent elasto-plastic theology are employed to study in a self-consistent fashion the deformation of the lithosphere subject to extension by means of a two-dimensional, finite-element code. A structural perturbation initially localizes elasto-plastic deformation only in its immediate vicinity. However, after 800,000 years have elapsed the localized zone of deformation takes off in a 'crack-like' fashion and travels to the bottom of the lithosphere in about 50,000 years time. When the plate is severed, thermal runaway is caused by mechanical heating triggered by the rapid energy transfer of the globally stored elastic energy into localized plastic dissipation in the ductile fault.

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Shear instability in a viscoelastic material as the cause of deep focus earthquakes

Cited by 232 publications

References 28 publications

Thermal structure and intermediate-depth seismicity in the Tohoku-Hokkaido subduction zones

Thermal structure and intermediate-depth seismicity in the Tohoku-Hokkaido subduction zones

Source and aftershock properties of the 1996 Flores Sea Deep Earthquake

Rapid conversion of elastic energy into plastic shear heating during incipient necking of the lithosphere

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