Upper mantle attenuation and velocity structure from measurements of differential<i>S</i>phases

Reid, Fiona; Woodhouse, John; Heijst, H. J. van

doi:10.1046/j.1365-246x.2001.01395.x

Cited by 37 publications

(46 citation statements)

References 32 publications

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“…Most body wave attenuation tomographies are based on variants of Equations (11.17) and (11.18) because they allow us to eliminate the contribution of the potentially uncertain seismic moment by measuring amplitude ratios of different seismic phases (e.g. Reid et al, 2001;Cheng & Kennett, 2002;Kennett & Abdullah, 2011). Early studies of Q in the Earth were primarily based on the decay of free oscillation peaks and long-period surface wave amplitudes (e.g.…”

Section: Description Of Seismic Wave Attenuation Basic Observables Amentioning

confidence: 99%

“…As an alternative to surface waves, Reid et al (2001) estimated t * from amplitude ratios of globally recorded S, SS and SSS waves. Also neglecting the effect of focusing, the t * measurements were inverted for a degree-8 model of Q μ in the upper mantle.…”

Section: D Attenuation Modelsmentioning

confidence: 99%

“…Dalton et al (2008) compared their global Q μ model to those of Romanowicz (1995), Reid et al (2001), Warren & Shearer (2002), Selby & Woodhouse (2002) and Gung & Romanowicz (2004). When truncated at degree 8, the correlation of these models was found to be mostly below 0.4 throughout the upper mantle.…”

Section: D Attenuation Modelsmentioning

confidence: 99%

See 2 more Smart Citations

Global Imaging of the Earth's Deep Interior: Seismic Constraints on (An)isotropy, Density and Attenuation

Trampert

Fichtner

2013

Physics and Chemistry of the Deep Earth

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Section: Description Of Seismic Wave Attenuation Basic Observables Amentioning

confidence: 99%

Section: D Attenuation Modelsmentioning

confidence: 99%

See 1 more Smart Citation

Global Imaging of the Earth's Deep Interior: Seismic Constraints on (An)isotropy, Density and Attenuation

Trampert

Fichtner

2013

Physics and Chemistry of the Deep Earth

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“…As much as the establishment of global digital networks of seismometers revolutionized global seismology in the past two decades, we believe that the SEM offers unique opportunities for the development in the next decade of a new generation of highquality mantle models and the determination of better earthquake source parameters (40). Ϫ1 dsϪ͐ S ray (␤Q) Ϫ1 ds distribution from (37). Large values of ␦t SSϪS * are often interpreted in terms of strong attenuation, whereas small values reflect weak attenuation.…”

Section: Perspectivesmentioning

confidence: 99%

The Spectral-Element Method, Beowulf Computing, and Global Seismology

Komatitsch

Ritsema

Tromp

2002

Science

222

154

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The propagation of seismic waves through Earth can now be modeled accurately with the recently developed spectral-element method. This method takes into account heterogeneity in Earth models, such as three-dimensional variations of seismic wave velocity, density, and crustal thickness. The method is implemented on relatively inexpensive clusters of personal computers, so-called Beowulf machines. This combination of hardware and software enables us to simulate broadband seismograms without intrinsic restrictions on the level of heterogeneity or the frequency content.

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“…Among these waveforms, many researchers choose SS wave because of its strong energy. For example, SS wave is used to do some researches on the anisotropy in the crust and upper-mantle at its bounce point (Yang and Fischer, 1994;Wolfe and Silver, 1998), global and large scale mantle tomography of S wave (Grand, 2002), the Q value distribution of S wave in the crust and upper-mantle (Bhattacharyya et al, 1996;Reid et al, 2001). At the same time, together with the arrival time difference of SdS on '410'and '660' discontinuities of upper-mantle, SS wave has been used to the researches on topography of global upper-mantle discontinuities and distribution for the thickness of transition zone (Lawrence and Shearer, 2006;Schmerr and Garnero, 2006).…”

Section: Introductionmentioning

confidence: 99%

Synthetic study on SS waveform splitting and complication

Zhou

et al. 2008

Acta Seismol. Sin.

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Some influential factors on the complication of SS waveform (with epicentral distance within 40°∼180°) are analyzed quantitatively by calculating the full-wave synthetic seismogram using propagation matrix method. Our results show that the transmission-conversion and reflection-conversion phases of S wave at the interface of Moho and free surface beneath bounce points are mainly responsible for the complication of SS waveform, the velocity contrast between the two sides of Moho boundary under SS bounce point also has great effects on the amplitudes of all the conversion and the reverberation phases; the properties of the crust at seismic station also play a role in the complication of SS waveform while the crustal thickness beneath bounce point is thinner relatively. At the same time, two sets of real SS waveform data at the two positions in eastern and western China are analyzed, and the splitting time between SS transverse component and radial component is measured by cross-correlation. Our analysis demonstrates that there is a positive correlation between crustal thickness and the splitting time because of the influences of adjacent conversion and reverberation phases, the splitting time in west with thick crust is obviously greater than that in the east with thin crust. Moreover, It is promising that one new method of measurement of crustal thickness will be developed by using the observed SS splitting time.

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Upper mantle attenuation and velocity structure from measurements of differentialSphases

Cited by 37 publications

References 32 publications

Global Imaging of the Earth's Deep Interior: Seismic Constraints on (An)isotropy, Density and Attenuation

Global Imaging of the Earth's Deep Interior: Seismic Constraints on (An)isotropy, Density and Attenuation

The Spectral-Element Method, Beowulf Computing, and Global Seismology

Synthetic study on SS waveform splitting and complication

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