scholarly article | Q13442814 |
P356 | DOI | 10.1007/978-3-319-15627-9_4 |
P50 | author | Barbara Romanowicz | Q2884020 |
P2093 | author name string | Thomas Bodin | |
Jean-Paul Montagner | |||
Yann Capdeville | |||
P2860 | cites work | Equation of State Calculations by Fast Computing Machines | Q5384234 |
Complex Shear Wave Velocity Structure Imaged Beneath Africa and Iceland | Q28139408 | ||
Subducted slabs stagnant above, penetrating through, and trapped below the 660 km discontinuity | Q29028190 | ||
Reversible jump Markov chain Monte Carlo computation and Bayesian model determination | Q29039791 | ||
The shuffling rotation of the Earth’s inner core revealed by earthquake doublets | Q30050356 | ||
Whole-mantle convection and the transition-zone water filter | Q34227876 | ||
Intra-oceanic subduction shaped the assembly of Cordilleran North America | Q34336859 | ||
Seismic evidence for sharp lithosphere-asthenosphere boundaries of oceanic plates | Q34977517 | ||
Evidence of micro-continent entrainment during crustal accretion | Q35040871 | ||
Waveform tomography reveals channeled flow at the base of the oceanic asthenosphere | Q43532297 | ||
Transdimensional inference in the geosciences. | Q44422571 | ||
Lithospheric layering in the North American craton | Q46219730 | ||
Global anisotropy and the thickness of continents | Q46743947 | ||
Reconstructing plate-motion changes in the presence of finite-rotations noise | Q47188560 | ||
Mapping tectonic deformation in the crust and upper mantle beneath Europe and the North Atlantic Ocean | Q47730932 | ||
Geophysical detection of relict metasomatism from an Archean (approximately 3.5 Ga) subduction zone. | Q50303240 | ||
Trans-dimensional geoacoustic inversion. | Q51616132 | ||
Preliminary reference Earth model | Q55868389 | ||
Monte Carlo sampling methods using Markov chains and their applications | Q55880695 | ||
A new global model for P wave speed variations in Earth's mantle | Q56136779 | ||
Reconstructions From Boundary Measurements | Q56139807 | ||
Seismic imaging: From classical to adjoint tomography | Q56268564 | ||
GLOBALMANTLETOMOGRAPHY: Progress Status in the Past 10 Years | Q56268565 | ||
The Iceland–Jan Mayen plume system and its impact on mantle dynamics in the North Atlantic region: Evidence from full-waveform inversion | Q56623444 | ||
A variational approach to the theory of the elastic behaviour of multiphase materials | Q56656594 | ||
Cluster analysis of global lower mantle tomography: A new class of structure and implications for chemical heterogeneity | Q56706402 | ||
Full waveform tomography of the upper mantle in the South Atlantic region: Imaging a westward fluxing shallow asthenosphere? | Q57254305 | ||
Multiscale full waveform inversion | Q57409214 | ||
On the computation of long period seismograms in a 3-D earth using normal mode based approximations | Q57574984 | ||
Towards global earth tomography using the spectral element method: a technique based on source stacking | Q57574989 | ||
Slow-downs and speed-ups of India–Eurasia convergence since ∼ 20 Ma : Data-noise, uncertainties and dynamic implications | Q57852446 | ||
Intrinsic versus extrinsic seismic anisotropy: The radial anisotropy in reference Earth models | Q57864780 | ||
Separating intrinsic and apparent anisotropy | Q57864800 | ||
Resolution analysis in full waveform inversion | Q57864854 | ||
Full waveform tomography for radially anisotropic structure: New insights into present and past states of the Australasian upper mantle | Q57864865 | ||
Full seismic waveform tomography for upper-mantle structure in the Australasian region using adjoint methods | Q57864888 | ||
Efficient numerical surface wave propagation through the optimization of discrete crustal models-a technique based on non-linear dispersion curve matching (DCM) | Q57864907 | ||
The adjoint method in seismology | Q57864927 | ||
Residual homogenization for seismic forward and inverse problems in layered media | Q57883278 | ||
Inversion of receiver functions without deconvolution—application to the Indian craton | Q57889899 | ||
Inferring upper-mantle structure by full waveform tomography with the spectral element method | Q57890004 | ||
Importance of crustal corrections in the development of a new global model of radial anisotropy | Q57890060 | ||
North American lithospheric discontinuity structure imaged byPsandSpreceiver functions | Q57890085 | ||
A three-dimensional radially anisotropic model of shear velocity in the whole mantle | Q57890304 | ||
Coupling spectral elements and modes in a spherical Earth: an extension to the ‘sandwich’ case | Q57890410 | ||
11 Inversion of surface waves: A review | Q57890430 | ||
The three-dimensional shear velocity structure of the mantle from the inversion of body, surface and higher-mode waveforms | Q57890550 | ||
Probabilistic surface reconstruction from multiple data sets: An example for the Australian Moho | Q58070883 | ||
SEISMIC TRAVELTIME TOMOGRAPHY OF THE CRUST AND LITHOSPHERE | Q58071013 | ||
Origin of Lateral Heterogeneities in the Upper Mantle Beneath South-east Australia from Seismic Tomography | Q58238191 | ||
Resolution potential of surface wave phase velocity measurements at small arrays | Q59845147 | ||
A multiple-scattering scheme for modelling surface wave propagation in isotropic and anisotropic three-dimensional structures | Q59845180 | ||
Is there seismic attenuation in the mantle? | Q59880075 | ||
Anisotropy in the Australasian upper mantle from Love and Rayleigh waveform inversion | Q60012219 | ||
The lithosphere–asthenosphere boundary and the tectonic and magmatic history of the northwestern United States | Q60109446 | ||
Probabilistic surface reconstruction of coastal sea level rise during the twentieth century | Q60146315 | ||
A 3-D shear velocity model of the crust and uppermost mantle beneath the United States from ambient seismic noise | Q60153970 | ||
On the robustness of global radially anisotropic surface wave tomography | Q60701153 | ||
SHdiff-SVdiff splitting in an isotropic Earth | Q60703214 | ||
Spectral-element simulations of global seismic wave propagation-I. Validation | Q60703248 | ||
Introduction to the spectral element method for three-dimensional seismic wave propagation | Q60703257 | ||
Structure of the European upper mantle revealed by adjoint tomography | Q60704000 | ||
The lithosphere–asthenosphere boundary and cratonic lithospheric layering beneath Australia from Sp wave imaging | Q60704286 | ||
Imaging Mantle Heterogeneity with Upper Mantle Seismic Discontinuities | Q60704440 | ||
Seismic tomography of the southern California crust based on spectral-element and adjoint methods | Q60704611 | ||
Seismic tomography, adjoint methods, time reversal and banana-doughnut kernels | Q60704634 | ||
Spectral element method for acoustic wave simulation in heterogeneous media | Q60709123 | ||
Vectorial tomography--I. Theory | Q60709334 | ||
Transdimensional inversion of ambient seismic noise for 3D shear velocity structure of the Tasmanian crust | Q60709780 | ||
Svelocity structure and radial anisotropy in the Aegean region from surface wave dispersion | Q60712466 | ||
Seismic receiver functions and the lithosphere–asthenosphere boundary | Q60719146 | ||
TheSreceiver functions: synthetics and data example | Q60719199 | ||
Effective-medium theory of sedimentary rocks | Q61761131 | ||
Lithosphere-asthenosphere interaction beneath the western United States from the joint inversion of body-wave traveltimes and surface-wave phase velocities | Q62019479 | ||
Seismic structure of Precambrian lithosphere: New constraints from broad-band surface-wave dispersion | Q63946347 | ||
On crustal corrections in surface wave tomography | Q63946375 | ||
Global anisotropic phase velocity maps for fundamental mode surface waves between 40 and 150 s | Q63946603 | ||
Constraints on Mantle Convection From Seismic Tomography | Q92081291 | ||
Homogenization and Two-Scale Convergence | Q98025298 | ||
P304 | page(s) | 105-144 | |
P577 | publication date | 2015-01-01 | |
P1476 | title | Interpreting Radial Anisotropy in Global and Regional Tomographic Models |
Q64231276 | Extrinsic Elastic Anisotropy in a Compositionally Heterogeneous Earth's Mantle | cites work | P2860 |
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