Fine Structure of a Postfailure Wadati‐Benioff Zone

Stolte, Christian; McNally, Karen; González-Ruiz, Jaime R.; Simila, G. W.; Reyes, Alfonso; Rebollar, Cecilio J.; Munguía, Luis; Mendoza, Luís Hurtado de

doi:10.1029/gl013i006p00577

Cited by 30 publications

(21 citation statements)

References 8 publications

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“…For both events, point source responses are calculated using the chosen fault mechanism and the crustal structure adopted by Mendoza and Hartzell [ 1988a] from the gradient velocity model of Stolte et al [1986]. A triangular source time function of 1-s duration is used for each point source.…”

Section: Methodsmentioning

confidence: 99%

“…This value is very similar to the strike observed in the centroidal source mechanisms computed for the 1985 Michoacan earthquake [e.g., Dziewonski et al, 1986;Priestley and Masters, 1986;Riedesel et al, 1986;Astiz et al, 1987]. The fault dip is fixed at 14 ø , which corresponds to the dip of the Wadati-Benioff zone inferred by Stolte et al [1986] from the hypocentral distribution of the aftershocks following the 1985 Michoacan and Zihuatanejo earthquakes. Table 1 lists the centroidal source parameters that have been previously computed by other investigators for the Playa Azul and Zihuatanejo earthquakes.…”

Section: Introductionmentioning

confidence: 95%

“…Mendez Masters, 1986; Riedesel et al, 1986]. In addition, aftershocks located in the source region map a zone elongated to the southeast [e.g., Stolte et al, 1986; Universidad Nacional Autonoma de Mexico (UNAM) $eismology Group, 1986]. These observations would additionally suggest that the September 21 earthquake represents the southeast continuation of interplate rupture that had been initiated during the 8.1 M s earthquake two days earlier [e.g., Astiz et al, 1987].…”

Section: Introductionmentioning

confidence: 99%

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Coseismic slip of two large Mexican earthquakes from teleseismic body waveforms: Implications for asperity interaction in the Michoacan Plate Boundary Segment

Mendoza¹

1993

J. Geophys. Res.

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Teleseismic body waves recorded for the October 25, 1981, Playa Azul and September 21, 1985, Zihuatanejo earthquakes in western Mexico were inverted to derive the distributions and depths of coseismic slip. Broadband P wave displacements and intermediate‐period records were included to incorporate a wide frequency band in the analysis. For the Zihuatanejo earthquake, digital SH records located away from the nodal directions were used in the inversion process. Nonnodal SH waveforms were not available for the Playa Azul earthquake, but additional azimuthal coverage was obtained by including selected worldwide analog P wave records. The results for the Playa Azul earthquake indicate that rupture occurred in two separate zones both updip and downdip of the point of initial nucleation with the majority of the slip concentrated in a circular region (15‐km radius) downdip from the hypocenter. The maximum slip in this downdip region exceeds 3.6 m and is at a depth of about 16 km. The computed seismic moment is 7.14 × 1026 dyn cm. Coseismic slip is observed to occur entirely within the area of reduced slip separating the two main shallow sources of the Michoacan earthquake that occurred almost 4 years later on September 19, 1985. For the Zihuatanejo earthquake the P and SH data suggest rupture over a larger area (30‐km radius) with a lower peak slip (2 m) and encompassing depths between 12 and 26 km. Slip is concentrated in an area adjacent to one of the major sources of the Michoacan earthquake and represents the southeastern continuation of rupture along the Cocos‐North America plate boundary. The corresponding seismic moment is 1.35 × 1027 dyn cm. The zones of peak slip observed for the Playa Azul, Zihuatanejo, and Michoacan earthquakes are interpreted as asperity regions that control the cessation and generation of large earthquakes within the Michoacan segment of the plate boundary. The stress drops within each of these asperities are observed to be very similar and may reflect a characteristic asperity strength for this portion of the subduction zone.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

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Coseismic slip of two large Mexican earthquakes from teleseismic body waveforms: Implications for asperity interaction in the Michoacan Plate Boundary Segment

Mendoza¹

1993

J. Geophys. Res.

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“…Open squares are in‐slab earthquakes [ Singh et al , 2000]; open circles are relocated earthquakes [ Pardo and Suarez , 1995]; solid triangles are seismic reflection data (Jalisco [ Michaud et al , 2000]); open triangle is from seismic refraction data (Oaxaca [ Nava et al , 1988]). Locations of megathrust main shocks (open diamonds) and their aftershocks (small circles) were given by Pacheco et al [1997] for Jalisco], Stolte et al [1986] for Michoacan, and Singh et al [2000] for Oaxaca. Bathymetry data were used to constrain the plate surface seaward of the trench [ Prol‐Ledesma et al , 1989; Pardo and Suarez , 1995].…”

Section: Thermal Modeling Of the Mexico Subduction Zonementioning

confidence: 99%

“…This was followed 2 days later by an M W 7.7 earthquake to the southeast. The majority of aftershocks for both events were located between 40 and 120 km from the trench [ UNAM Seismology Group , 1986; Stolte et al , 1986]. The width of the aftershock area is slightly narrower in the northwest part of the 19 September rupture area, with the landward limit of the aftershocks ∼80 km from the trench.…”

Section: Mexico Seismogenic Zonementioning

confidence: 99%

Thermal models of the Mexico subduction zone: Implications for the megathrust seismogenic zone

et al. 2002

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[1] It has been proposed that the seismogenic zone of subduction thrust faults is primarily controlled by temperature or rock composition changes. We have developed numerical models of the thermal structure of the Mexico subduction zone to examine the factors that affect the temperature of the subduction thrust fault. Although the oceanic plates subducting beneath Mexico are young, the top of the oceanic plate at the trench is cool, because of the lack of a thick cover of insulating sediments. Marine heat flow observations suggest that hydrothermal circulation may further cool the oceanic plate. This results in a cool subduction thrust fault, where the brittle part of the fault extends to depths of over 40 km. At these depths, even slight frictional heating may have significant effects on temperature along the thrust fault, particularly for regions with a high convergence rate and shallow plate dip. With the addition of a small amount of frictional heating, the temperatures of the deep (30-40 km) thrust fault are increased by over 200°C. As the observed downdip limit of rupture in recent well-constrained megathrust earthquakes is confined to depths above the intersection of the thrust fault and the continental Moho, a temperature of 350°C may control the downdip extent of the seismogenic zone. Thus, in order to be consistent with the observed shallow rupture areas, it is necessary to include a small amount of frictional heating, corresponding to an average shear stress of 15 MPa.INDEX TERMS: 3015 Marine Geology and Geophysics: Heat flow (benthic) and hydrothermal processes; 3040 Marine Geology and Geophysics: Plate tectonics (8150, 8155, 8157, 8158); 7230 Seismology: Seismicity and seismotectonics; 8130 Tectonophysics: Evolution of the Earth: Heat generation and transport; KEYWORDS: thermal models, subduction zone, megathrust earthquakes, seismogenic zone, heat flow, Mexico subduction zone Citation: Currie, C. A., R. D. Hyndman, K. Wang, and V. Kostoglodov, Thermal models of the Mexico subduction zone: Implications for the megathrust seismogenic zone,

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