Global synthetic seismograms using a 2-D finite-difference method

Li, Dunzhu; Helmberger, Donald V.; Clayton, Robert W.; Sun, Daoyuan

doi:10.1093/gji/ggu050

Cited by 81 publications

(72 citation statements)

References 45 publications

(44 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Even for a variety of tested basin depths, impedance contrasts and even for more realistic geologic profiles [e.g., Boore and Joyner , ], the differences in amplification remain (see supporting information Figure S1). Lastly, we note that these transfer functions are confirmed through 2‐D finite difference simulations [ Li et al ., ], with only minor differences caused by path effects such as scattering and a conversion of wave types at the edge of the sedimentary basin.…”

Section: Simple Basin Examplementioning

confidence: 99%

Earthquake ground motion amplification for surface waves

Bowden

Tsai

2017

Geophysical Research Letters

View full text Add to dashboard Cite

Surface waves from earthquakes are known to cause strong damage, especially for larger structures such as skyscrapers and bridges. However, common practice in characterizing seismic hazard at a specific site considers the effect of near‐surface geology on only vertically propagating body waves. Here we show that surface waves have a unique and different frequency‐dependent response to known geologic structure and that this amplification can be analytically calculated in a manner similar to current hazard practices. Applying this framework to amplification in the Los Angeles Basin, we find that peak ground accelerations for certain large regional earthquakes are underpredicted if surface waves are not properly accounted for and that the frequency of strongest ground motion amplification can be significantly different. Including surface‐wave amplification in hazards calculations is therefore essential for accurate predictions of strong ground motion for future San Andreas Fault ruptures.

show abstract

Section: Simple Basin Examplementioning

confidence: 99%

Earthquake ground motion amplification for surface waves

Bowden

Tsai

2017

Geophysical Research Letters

View full text Add to dashboard Cite

show abstract

“…A GPU version of the 8th order staggeredgrid 2D finite difference code is used for the numerical computation (Li et al, 2012). 1D synthetic waveforms are obtained through the frequency-wavenumber integration (Zhu and Rivera, 2002).…”

Section: D Salton Trough Modelmentioning

confidence: 99%

Source Parameters of the Shallow 2012 Brawley Earthquake, Imperial Valley

Chu

Helmberger

2013

Bulletin of the Seismological Society of America

View full text Add to dashboard Cite

Resolving earthquake parameters, especially depth, is difficult for events occurring within basins because of issues involved with separating source properties from propagational path effects. Here, we demonstrate some advantages of using a combination of teleseismic and regional waveform data to improve resolution following a bootstrapping approach. Local SS-S differential arrivals from a foreshock are used to determine a local layered model which can then be used to model teleseismic depth phases: pP, sP, and sS. Using the cut-and-paste (CAP) method for which all strike (θ), dip (δ), rake (λ), and depth variations are sampled for several crustal models. We find that regional data prove the most reliable at fixing the strike, whereas the depth is better constrained by teleseismic data. Weighted solutions indicate a nearly pure strike-slip mechanism (θ 59° 1°) with a centroid depth of about 4.0 km and an M w of 5.4 for the mainshock of the 2012 Brawley earthquake. Online Material:Figures showing examples of waveform fits, comparison of synthetic teleseismic waveforms using different grid sizes in the FD calculation, effect of soft sediment on teleseismic Green's functions, and sensitivity of regional and teleseismic data on the focal mechanisms.

show abstract

“…In contrast to previous studies using triplicated waveform modeling based on 1‐D velocity structure, we simulated the 2‐D regional elastic wavefield using the Spectrum‐Element Method with the implementation of Komatitsch and Tromp (, ). We inserted the moment tensor source following the approach of Li et al (). To resolve the synthetics with high‐frequency content of up to 0.8 Hz, we set the Spectrum‐Element Method grid to 2 km throughout the entire domain, and the time step to 0.005 and 0.01 s for P and SH wave, respectively, which transfers to 1,750 × 1,500 grid points (3,500 km in the horizontal and 3,000 km in the vertical).…”

Section: Methodsmentioning

confidence: 99%

Mantle Transition Zone Structure Beneath Northeast Asia From 2‐D Triplicated Waveform Modeling: Implication for a Segmented Stagnant Slab

et al. 2019

View full text Add to dashboard Cite

The structure of the mantle transition zone (MTZ) in subduction zones is essential for understanding subduction dynamics in the deep mantle and its surface responses. We constructed the P (Vp) and SH velocity (Vs) structure images of the MTZ beneath Northeast Asia based on two‐dimensional (2‐D) triplicated waveform modeling. In the upper MTZ, a normal Vp but 2.5% low Vs layer compared with IASP91 are required by the triplication data. In the lower MTZ, our results show a relatively higher‐velocity layer (+2% Vp and −0.5% Vs compared to IASP91) with a thickness of ~140 km and length of ~1,200 km atop the 660‐km discontinuity. Taking this anomaly as the stagnant slab and considering the plate convergence rate of 7–10 cm/year in the western Pacific region during the late Cenozoic, we deduced that the stagnant slab has a subduction age of less than 30 Ma. This suggests that the observed stagnancy of the slab in the MTZ beneath Northeast Asia may have occurred no earlier than the Early Oligocene. From the constraints derived individually on Vp and Vs structures, high Vp/Vs ratios are obtained for the entire MTZ beneath Northeast Asia, which may imply a water‐rich and/or carbonated environment. Within the overall higher‐velocity stagnant slab, a low‐velocity anomaly was further detected, with a width of ~150 km, Vp and Vs reductions of 1% and 3% relative to IASP91. Such a gap may have provided a passage for hot deep mantle materials to penetrate through the thick slab and feed the Changbaishan volcano.

show abstract

Global synthetic seismograms using a 2-D finite-difference method

Cited by 81 publications

References 45 publications

Earthquake ground motion amplification for surface waves

Earthquake ground motion amplification for surface waves

Source Parameters of the Shallow 2012 Brawley Earthquake, Imperial Valley

Mantle Transition Zone Structure Beneath Northeast Asia From 2‐D Triplicated Waveform Modeling: Implication for a Segmented Stagnant Slab

Contact Info

Product

Resources

About