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1

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Multiple scattering of SH waves in 2-D elastic media with distributed cracks (1995)

Murai, Yoshio ; Kawahara, Jun ; Yamashita, Teruo

Oxford, UK : Blackwell Publishing Ltd

Geophysical journal international 122 (1995), S. 0

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ISSN: 1365-246X

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Geosciences

Notes: We compute synthetic seismograms of SH waves that are multiply scattered by randomly distributed cracks. All the cracks are assumed to have the same length and strike direction; the crack surfaces are assumed to be stress-free, or to undergo viscous friction. We analyse the deterministic wave equation, and rigorously treat multiple crack interactions. We first calculate the wavefield in the wavenumber domain, and then we obtain the time-domain solution by its Fourier transform.A plane wave whose time dependence is described by the Ricker wavelet is assumed to be incident upon the region of crack distribution. The scattered waves are efficiently excited when the half-wavelength of the incident wave is close to or shorter than the crack length. High-wavenumber components are shown to be more abundant in the scattered waves when the crack distribution is denser. The time delay of the arrival of the primary wave, due to crack scattering, is shown to be prominent when the wavelength of the incident wave is much longer than the crack length. When the crack surfaces are subject to viscous friction, both the amplitudes of the scattered waves and the time delay of the primary-wave arrivals are smaller than those for the case of stress-free crack surfaces. When the crack distribution is statistically homogeneous, the calculated attenuation coefficient Q−1 and phase velocity v of the primary wave are generally consistent with those obtained by a stochastic analysis based on Foldy's approximation. A short analysis on the effect of inhomogeneous crack distribution shows that the wavenumber at which Q−1 is at its peak value is smaller than that expected from the stochastic analysis for homogeneous crack distribution.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1365-246X.1995.tb06846.x

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2

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Apparent Critical Slip Displacement Caused By the Existence of A Fault Zone (1996)

Yamashita, Teruo ; Fukuyama, Eiichi

Oxford, UK : Blackwell Publishing Ltd

Geophysical journal international 125 (1996), S. 0

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ISSN: 1365-246X

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Geosciences

Notes: We study the influence of a fault zone on the critical slip displacement that is estimated seismologically outside the fault zone theoretically. It is generally known that the critical slip displacement plays a key role in characterizing the earthquake rupture process. the fault zone is modelled as a zone in which a number of parallel pre-existing cracks are distributed. A relatively simple rupture model is assumed in the analysis to elicit only the fundamental effect of dynamic interactions among the cracks on the estimate of the critical slip displacement. the rupture is assumed to occur instantaneously over each crack, and crack lengths are fixed in the analysis. the multiple interactions among the cracks are treated rigorously in the time domain using the boundary-integral equation method.Our calculation shows that apparent slip-weakening behaviour is observed outside the fault zone, and that it is caused by elastic-wave scattering due to the cracks distributed in the fault zone. the apparent critical slip displacement is shown to be larger when the distribution density of the pre-existing cracks is larger and/or the fault zone width is greater. It is also shown that the apparent critical slip displacement caused by crack scattering is generally larger than the critical slip displacement inherent in the rupture. As the distribution density of the pre-existing cracks increases, the difference in both displacements tends to increase.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1365-246X.1996.tb00011.x

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The paradox of smooth and abrupt bends in two-dimensional in-plane shear-crack mechanics (1996)

Tada, Taku ; Yamashita, Teruo

Oxford, UK : Blackwell Publishing Ltd

Geophysical journal international 127 (1996), S. 0

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ISSN: 1365-246X

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Geosciences

Notes: It is pointed out, in the context of the boundary integral equation method (BIEM), that, in the mechanics of 2-D curved in-plane shear cracks, a smooth curve, along which the crack orientation changes continuously, and an abrupt kink, across which it changes discontinuously, are not equivalent to each other. The discrepancy is illustrated by numerical results, and a set of conceptual models is used to demonstrate analytically how the equations that govern the crack mechanics have inherently distinct forms depending on whether the crack orientation changes continuously or abruptly across a bend, as long as one abides by the principles of linear elasticity theory. This has serious implications for the numerical treatment of a curved crack, which can be modelled as a chain of finite elements that are connected either smoothly or at abrupt kinks, the two methods producing different numerical outcomes. No similar paradox arises in the cases of anti-plane shear or open in-plane cracks.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1365-246X.1996.tb04058.x

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4

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Earthquake rupture complexity due to dynamic nucleation and interaction of subsidiary faults (1994)

Yamashita, Teruo ; Umeda, Yasuhiro

Springer

Pure and applied geophysics 143 (1994), S. 89-116

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ISSN: 1420-9136

Keywords: Crack interaction ; elastic wave ; dynamic rupture ; earthquake bright spot

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences , Physics

Notes: Abstract We numerically study the dynamic interaction of propagating cracks. It is assumed that propagating cracks can nucleate and drive subsidiary cracks because of shear strain enhancement near the propagating crack tips. The critical strain fracture criterion is assumed in the analysis. Intense interaction is expected to occur among the cracks. All the cracks are assumed to be parallel and antiplane strain deformation is assumed in the computation. In the interaction of two non-coplanar cracks, a strain shadow is formed in the neighborhood of each crack because of the strain release by the introduction of the crack. The growth of each crack is accelerated when the propagating tips of each crack are outside of the strain shadow of the other crack. In general, the crack tips enter the strain shadow, and the crack tips decelerate. The calculation shows that only one of the two cracks can continue to grow, and the other's growth is decelerated and arrested. If we can assume that the suite of cracks interact in a pairwise manner only, then this may suggest that only a limited number of cracks can continue to grow during the final stage of the rupture process. Hence the crack interaction causes complexity in dynamic earthquake faulting. The concepts of barrier and asperity have been employed by many researchers for the interpretation of complex seismic wave data. However, the physical realities of such concepts are obscure. Our calculations show that dynamic crack interactions can produce barriers and asperities in some cases; the crack tip deceleration or arrest due to the interactions among non-coplanar cracks can be interpreted as being due to a barrier. The dynamic coalescence among the coplanar cracks can be regarded as an asperity. Umeda found a localized area that strongly radiates high-frequency seismic waves in the epicentral areas of some large shallow earthquakes. He defined this as an “earthquake bright spot.” Our analysis implies that only a limited number of cracks continue to grow when many interactive cracks nucleate, and that all other cracks stop extending soon after nucleation. Hence, if the nucleation and termination of several cracks occur in a localized area, it will be observed seismologically as an earthquake bright spot. This is because it is theoretically known that the sudden termination of crack growth and dynamic crack coalescence efficiently emits high-frequency elastic waves.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00874325

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5

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Scattering of elastic waves by a fracture zone containing randomly distributed cracks (1992)

Kawahara, Jun ; Yamashita, Teruo

Springer

Pure and applied geophysics 139 (1992), S. 121-144

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ISSN: 1420-9136

Keywords: Fracture zone ; cracks ; scattering ; friction ; attenuation ; phase velocity ; transmitted and reflected waves

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences , Physics

Notes: Abstract We theoretically study the scattering ofP, SV andSH waves by a zonal distribution of cracks, which simulates a fault fracture zone. An investigation is conducted how the geometrical properties of the crack distribution and the frictional characteristics of the crack surface are reflected in the attenuation and dispersion of incident waves, as well as in the amplitudes of the transmitted and reflected waves from the zone. If the crack distribution within the fault zone changes temporally during the preparation process of the expected earthquake, it will be important for earthquake prediction to monitor it, utilizing the scattering-induced wave phenomena. We consider the two-dimensional problem. Aligned cracks with the same length are assumed to be randomly distributed in a zone with a finite width, on which elastic waves are assumed to be incident. The distribution of cracks is assumed to be homogeneous and sparse. The crack surface is assumed to be stress-free, or to undergo viscous friction; the latter case simulates fluid-filled cracks. The opening displacement of the crack is assumed to be negligibly small. The idea of the mean wave formalism is employed in the analysis, and Foldy's approximation is assumed. When the crack surface is stress-free, it is commonly observed for every wave mode (P, SV andSH) that the attenuation coefficientQ −1 peaks aroundka∼1, the phase velocity is almost independent ofk in the rangeka〈1 and it increases monotonically withk in the rangeka〉1, wherek is the intrinsicS wavenumber anda is the half length of the crack. The effect of the friction is to shift the peak ofQ −1 and the corner of the phase velocity curve to the low wavenumber range. The high wavenumber asymptote ofQ −1 is proportional tok −1 independently of model parameters and the wave modes. If the seismological observation thatQ −1 ofS waves has a peak at around 0.5 Hz in the earth's crust is combined with our results, the upper limit of crack size within the crust is estimated about 4 km. The information regarding the transmitted and reflected waves, such as the high wavenumber limit of the amplitude of the transmitted wave etc., allows estimation of the strength of the friction.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00876828

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6

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Attenuation and dispersion ofSH waves due to scattering by randomly distributed cracks (1990)

Yamashita, Teruo

Springer

Pure and applied geophysics 132 (1990), S. 545-568

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ISSN: 1420-9136

Keywords: Cracks ; scattering ; attenuation ; phase velocity ; SH waves

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences , Physics

Notes: Abstract The effect of randomly distributed cracks on the attenuation and dispersion ofSH waves is theoretically studied. If earthquake ruptures are caused by sudden coalescence of preexisting cracks, it will be crucial for earthquake prediction to monitor the temporal variation of the crack distribution. Our aim is to investigate how the property of crack distribution is reflected in the attenuation and dispersion of elastic waves. We introduce the stochastic property, in the mathematical analysis, for the distributions of crack location, crack size and crack orientation. The crack size distribution is assumed to be described by a power law probability density (p(a) ∞ a −γ fora min≤a≤a max according to recent seismological and experimental knowledge, wherea is a half crack length and the range 1≤γ≤3 is assumed. The distribution of crack location is assumed to be homogeneous for the sake of mathematical simplicity, and a low crack density is assumed. The stochastic property of each crack is assumed to be independent of that of the other cracks. We assume two models, that is, the aligned crack model and the randomly oriented crack model, for the distribution of crack orientation. All cracks are assumed to be aligned in the former model. The orientation of each crack is assumed to be random in the latter model, and the homogeneous distribution is assumed for the crack orientation. The idea of the mean wave formalism is employed in the analysis, and Foldy's approximation is assumed. We observe the following features common to both the aligned crack model and the randomly oriented crack model. The attenuation coefficientQ −1 decays in proportion tok −1 in the high frequency range and its growth is proportional tok 2 in the low frequency range, wherek is the intrinsic wave number. This asymptotic behavior is parameter-independent, too. The attenuation coefficientQ −1 has a broader peak as γ increases and/ora min/a max decreases. The nondimensional peak wave numberk p a max at whichQ −1 takes the peak value is almost independent ofa min/a max for γ=1 and 2 while it considerably depends ona min/a max for γ=3. The phase velocity is almost independent ofk in the rangeka max〈1 and increases monotonically ask increases in the rangeka max〉1. While the magnitude ofQ −1 and the phase velocity considerably depend on the orientation of the crack in the aligned crack model, the above feature does not depend on the crack orientation. The accumulation of seismological measurements suggests thatQ −1 ofS waves has a peak at around 0.5 Hz. If this observation is combined with our theoretical results onk p a max, the probable range ofa max of the crack distribution in the earth can be estimated for γ=1 or 2. If we assume 4 km/sec as theS wave velocity of the matrix medium,a max is estimated to range from 2 to 5 km. We cannot estimatea max in a narrow range for γ=3.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00876929

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