Seismic waves due to a dislocation source model in a multi-layered medium. II. Numerical calculations for a point source.

AbstractIn this paper, numerical computations are carried out to investigate the seismo-electromagnetic signals arising from the motional induction effect due to an earthquake source embedded in 3-D multi-layered media. First, our numerical computation approach that combines discrete wavenumber method, peak-trough averaging method, and point source stacking method is introduced in detail. The peak-trough averaging method helps overcome the slow convergence problem, which occurs when the source–receiver depth difference is small, allowing us to consider any focus depth. The point source stacking method is used to deal with a finite fault. Later, an excellent agreement between our method and the curvilinear grid finite-difference method for the seismic wave solutions is found, which to a certain degree verifies the validity of our method. Thereafter, numerical computation results of an air–solid two-layer model show that both a receiver below and another one above the ground surface will record electromagnetic (EM) signals showing up at the same time as seismic waves, that is, the so-called coseismic EM signals. These results suggest that the in-air coseismic magnetic signals reported previously, which were recorded by induction coils hung on trees, can be explained by the motional induction effect or maybe other seismo-electromagnetic coupling mechanisms. Further investigations of wave-field snapshots and theoretical analysis suggest that the seismic-to-EM conversion caused by the motional induction effect will give birth to evanescent EM waves when seismic waves arrive at an interface with an incident angle greater than the critical angle θc = arcsin(Vsei/Vem), where Vsei and Vem are seismic wave velocity and EM wave velocity, respectively. The computed EM signals in air are found to have an excellent agreement with the theoretically predicted amplitude decay characteristic for a single frequency and single wavenumber. The evanescent EM waves originating from a subsurface interface of conductivity contrast will contribute to the coseismic EM signals. Thus, the conductivity at depth will affect the coseismic EM signals recorded nearby the ground surface. Finally, a fault rupture spreading to the ground surface, an unexamined case in previous numerical computations of seismo-electromagnetic signals, is considered. The computation results once again indicate the motional induction effect can contribute to the coseismic EM signals.

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A PSEUDO POINT-SOURCE MODEL FOR OFF MIYAGI INTRASLAB EARTHQUAKE ON MAY 26, 2003

Journal of Japan Society of Civil Engineers Ser A1 (Structural Engineering & Earthquake Engineering (SE/EE)) ◽

10.2208/jscejseee.70.i_818 ◽

2014 ◽

Vol 70 (4) ◽

pp. I_818-I_829 ◽

Cited By ~ 1

Author(s):

Atsushi WAKAI ◽

Yosuke NAGASAKA ◽

Atsushi NOZU

Keyword(s):

Point Source ◽

Source Model ◽

Intraslab Earthquake

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Seismic Waves in a Laterally Inhomogeneous Layered Medium, Part I: Theory

Journal of Applied Mechanics ◽

10.1115/1.2787293 ◽

1997 ◽

Vol 64 (1) ◽

pp. 50-58 ◽

Cited By ~ 11

Author(s):

Ruichong Zhang ◽

Liyang Zhang ◽

Masanobu Shinozuka

Keyword(s):

Wave Field ◽

Half Space ◽

Seismic Waves ◽

Scattered Wave ◽

Inhomogeneous Layer ◽

Dislocation Source ◽

Seismic Dislocation ◽

Body Forces ◽

The Mean ◽

Layered Half Space

Seismic waves in a layered half-space with lateral inhomogeneities, generated by a buried seismic dislocation source, are investigated in these two consecutive papers. In the first paper, the problem is formulated and a corresponding approach to solve the problem is provided. Specifically, the elastic parameters in the laterally inhomogeneous layer, such as P and S wave speeds and density, are separated by the mean and the deviation parts. The mean part is constant while the deviation part, which is much smaller compared to the mean part, is a function of lateral coordinates. Using the first-order perturbation approach, it is shown that the total wave field may be obtained as a superposition of the mean wave field and the scattered wave field. The mean wave field is obtainable as a response solution for a perfectly layered half-space (without lateral inhomogeneities) subjected to a buried seismic dislocation source. The scattered wave field is obtained as a response solution for the same layered half-space as used in the mean wave field, but is subjected to the equivalent fictitious distributed body forces that mathematically replace the lateral inhomogeneities. These fictitious body forces have the same effects as the existence of lateral inhomogeneities and can be evaluated as a function of the inhomogeneity parameters and the mean wave fleld. The explicit expressions for the responses in both the mean and the scattered wave fields are derived with the aid of the integral transform approach and wave propagation analysis.

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On the point-source approximation of earthquake dynamics

Annals of Geophysics ◽

10.4401/ag-6479 ◽

2014 ◽

Vol 57 (3) ◽

Author(s):

Andrea Bizzarri

Keyword(s):

Point Source ◽

Seismic Waves ◽

Single Point ◽

Seismic Source ◽

Transition Process ◽

Point Sources ◽

Multiple Point ◽

Earthquake Dynamics ◽

Planar Fault ◽

Source Models

The focus on the present study is on the point-source approximation of a seismic source. First, we compare the synthetic motions on the free surface resulting from different analytical evolutions of the seismic source (the Gabor signal (G), the Bouchon ramp (B), the Cotton and Campillo ramp (CC), the Yoffe function (Y) and the Liu and Archuleta function (LA)). Our numerical experiments indicate that the CC and the Y functions produce synthetics with larger oscillations and correspondingly they have a higher frequency content. Moreover, the CC and the Y functions tend to produce higher peaks in the ground velocity (roughly of a factor of two). We have also found that the falloff at high frequencies is quite different: it roughly follows ω−2 in the case of G and LA functions, it decays more faster than ω−2 for the B function, while it is slow than ω−1 for both the CC and the Y solutions. Then we perform a comparison of seismic waves resulting from 3-D extended ruptures (both supershear and subshear) obeying to different governing laws against those from a single point-source having the same features. It is shown that the point-source models tend to overestimate the ground motions and that they completely miss the Mach fronts emerging from the supershear transition process. When we compare the extended fault solutions against a multiple point-sources model the agreement becomes more significant, although relevant discrepancies still persist. Our results confirm that, and more importantly quantify how, the point-source approximation is unable to adequately describe the radiation emitted during a real world earthquake, even in the most idealized case of planar fault with homogeneous properties and embedded in a homogeneous, perfectly elastic medium.

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Analysis of Thermal Radiation Models for Large Open Pool Fire on Ship Deck

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.470.259 ◽

2013 ◽

Vol 470 ◽

pp. 259-262

Author(s):

Li Bin Ding ◽

Jin Yun Pu ◽

Kai Ren

Keyword(s):

Heat Flux ◽

Thermal Radiation ◽

Point Source ◽

Engineering Design ◽

Source Model ◽

Heat Fluxes ◽

Pool Fire

Three radiation models are discussed in the present paper. The heat fluxes vary considerably between different methods. In all models, fluxes vary highly on the position of nearing the flame and are almost identical on the far away position. Heat fluxes calculated from point source model is less than other two models, and Shokri-Beyler model is highest. Shokri-Beyler method is most applicable at heat fluxes greater than 5 KW/m2 and recommended in engineering design, and Mudan model is not applicable for calculating the heat flux nearing the flame.

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Offset‐dependent geometrical spreading in a layered medium

Geophysics ◽

10.1190/1.1442860 ◽

1990 ◽

Vol 55 (4) ◽

pp. 492-496 ◽

Cited By ~ 54

Author(s):

Bjørn Ursin

Keyword(s):

Point Source ◽

Taylor Series ◽

Layered Medium ◽

Exact Expression ◽

Second Order ◽

Geometrical Spreading ◽

Approximate Expressions

The geometrical spreading for a point source in a horizontally layered medium has been computed by Ursin (1978) and Hubral (1978) as a Taylor series in the offset coordinate. The coefficients in the Taylor series depend on the thicknesses and the velocities of the layers. Here, I start with the exact expression for geometrical spreading and show that it can be expressed as a function of the velocity in the first layer, the offset, and the first‐ and second‐order traveltime derivatives. A shifted hyperbolic traveltime approximation (Castle, 1988) and the usual hyperbolic traveltime approximation are used to derive approximate expressions for geometrical spreading. These expressions can also be derived from a truncated Taylor series by making additional approximations, but this procedure is not so obvious.

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