Improving Absolute Hypocenter Accuracy with 3‐D Pg and Sg Body‐Wave Inversion Procedures and Application to Earthquakes in the Central Alps Region

ABSTRACT Oceanic plate seismicity is generally dominated by normal and strike-slip faulting associated with active spreading ridges and transform faults. Fossil structural fabrics inherited from spreading ridges also host earthquakes. The Indian Oceanic plate, considered quite active seismically, has hosted earthquakes both on its active and fossil fault systems. The 4 December 2015 Mw 7.1 normal-faulting earthquake, located ∼700 km south of the southeast Indian ridge in the southern Indian Ocean, is a rarity due to its location away from the ridge, lack of association with any mapped faults and its focal depth close to the 800°C isotherm. We present results of teleseismic body-wave inversion that suggest that the earthquake occurred on a north-northwest–south-southeast-striking normal fault at a depth of 34 km. The rupture propagated at 2.7 km/s with compact slip over an area of 48×48 km2 around the hypocenter. Our analysis of the background tectonics suggests that our chosen fault plane is in the same direction as the mapped normal faults on the eastern flanks of the Kerguelen plateau. We propose that these buried normal faults, possibly the relics of the ancient rifting might have been reactivated, leading to the 2015 midplate earthquake.

Download Full-text

Seismic wave energy inferred from long-period body wave inversion

Bulletin of the Seismological Society of America ◽

10.1785/bssa0780051707 ◽

1988 ◽

Vol 78 (5) ◽

pp. 1707-1724

Author(s):

Masayuki Kikuchi ◽

Yoshio Fukao

Keyword(s):

Seismic Wave ◽

Wave Energy ◽

Body Wave ◽

Empirical Relation ◽

P Waves ◽

Average Value ◽

Long Period ◽

Wave Inversion ◽

Moment Ratio ◽

Order Of Magnitude

Abstract The seismic wave energy is evaluated for 35 large earthquakes by inverting far-field long-period P waves into the multiple-shock sequence. The results show that the seismic wave energy thus obtained is systematically less than that inferred from the Gutenberg-Richter's formula with the seismic magnitude. The difference amounts to one order of magnitude. The results also show that the energy-moment ratio is well confined to a narrow range: 10−6 < ES/Mo < 10−5 with the average of ∼5 × 10−6. This average value is exactly one order of magnitude as small as the energy-moment ratio inferred from the Gutenberg-Richter's formula using the moment magnitude. Comparing the energy-moment ratio with Δσo/2μ, where Δσo and μ are the stress drop and the rigidity, we obtain an empirical relation: ES/Mo ∼ 0.1 × Δσ0/2μ. Such a relation can be interpreted in terms of a subsonic rupture where the energy loss due to cohesion is not negligible to the seismic wave energy.

Download Full-text

Analysis of Tsunami Inundation due in Pangandaran Tsunami Earthquake in South Java Area Based on Finite Faults Solutions Model

Jurnal Penelitian Fisika dan Aplikasinya (JPFA) ◽

10.26740/jpfa.v10n2.p114-124 ◽

2020 ◽

Vol 10 (2) ◽

pp. 114

Author(s):

Ramadhan Priadi ◽

Dede Yunus ◽

Berlian Yonanda ◽

Relly Margiono

Keyword(s):

Fault Plane ◽

Body Wave ◽

Scaling Law ◽

Source Mechanism ◽

Inversion Method ◽

Tsunami Modeling ◽

Residential Areas ◽

North West ◽

Wave Inversion ◽

Run Up

On July 17, 2006 an earthquake with a magnitude of 7.7 triggered a tsunami that struck 500 km of the coast in the south of the island of Java. The tsunami generated is classified as an earthquake tsunami because the waves generated were quite large compared to the strength of the earthquake. The difference in the strength of the earthquake and the resulting tsunami requires a tsunami modeling study with an estimated fault area in addition to using aftershock and scaling law. The purpose of this study is to validate tsunamis that occur based on the estimation of the source mechanism and the area of earthquake faults. Determination of earthquake source mechanism parameters using the Teleseismic Body-Wave Inversion method that uses teleseismic waveforms with the distance recorded waveform from the source between Whereas, tsunami modeling is carried out using the Community Model Interface for Tsunami (commit) method. Fault plane parameters that obtained were strike , dip , and rake with dominant slip pointing up to north-north-west with a maximum value of 1.7 m. The fault plane is estimated to have a length of 280 km in the strike direction and a width of 102 km in the dip direction. From the results of the tsunami modeling, the maximum inundation area is 0.32 km2 in residential areas flanked by Pangandaran bays and the maximum run-up of 380.96 cm in Pasir Putih beach area. The tsunami modeling results in much smaller inundation and run-up from field observations, it was assumed that the fault plane segmentation had occurred due to the greater energy released than the one from the fault area, causing waves much larger than the modeling results.

Download Full-text

Source mechanisms and focal depths of East African earthquakes using Rayleigh-wave inversion and body-wave modelling

Geophysical Journal International ◽

10.1111/j.1365-246x.1985.tb04328.x ◽

1985 ◽

Vol 83 (3) ◽

pp. 563-614 ◽

Cited By ~ 136

Author(s):

G. N. Shudofsky

Keyword(s):

Rayleigh Wave ◽

Body Wave ◽

East African ◽

Wave Modelling ◽

Wave Inversion ◽

Source Mechanisms

Download Full-text

East African earthquake body wave inversion with implications for continental structure and deformation

Geophysical Journal International ◽

10.1111/j.1365-246x.1988.tb02271.x ◽

1988 ◽

Vol 94 (3) ◽

pp. 503-518 ◽

Cited By ~ 26

Author(s):

G. S. Wagner ◽

C. A. Langston

Keyword(s):

Body Wave ◽

East African ◽

Wave Inversion

Download Full-text

Slab Break-offs in the Alpine Subduction Zone

10.5194/se-2019-102 ◽

2019 ◽

Author(s):

Emanuel D. Kästle ◽

Claudio Rosenberg ◽

Lapo Boschi ◽

Nicolas Bellahsen ◽

Thomas Meier ◽

...

Keyword(s):

Deep Structure ◽

Body Wave ◽

Eastern Alps ◽

Central Alps ◽

Slab Geometry ◽

Tomographic Images ◽

Velocity Anomaly ◽

The Alps ◽

Geological Constraints ◽

European Plate

Abstract. After the onset of plate collision in the Alps, at 32–34 Ma, the deep structure of the orogen is inferred to have changed dramatically: European plate break-offs in various places of the Alpine arc, as well as a possible reversal of subduction polarity in the eastern Alps have been proposed. We review body-wave tomographic studies, compare them to our surface-wave-derived model for the uppermost 200 km, and reinterpret them in terms of slab geometries. We infer that the shallow subducting portion of the European plate is likely detached under both the western and eastern (but not the central) Alps. The Alps-Dinarides transition may be explained by a combination of European and Adriatic subduction. This would imply that the deep, high-velocity anomaly (> 200 km depth) mapped by tomographers under the eastern Alps is a detached segment of the European plate. The shallower fast anomaly (100–200 km depth) can be ascribed to European or Adriatic subduction, or both. These findings are compared to previously proposed models for the eastern Alps in terms of slab geometry, but also integrated in a new, alternative geodynamic scenario that best fits both tomographic images and geological constraints.

Download Full-text