Joint seismic, geodynamic and mineral physical constraints on three-dimensional mantle heterogeneity: Implications for the relative importance of thermal versus compositional heterogeneity

Simmons, N. A.; Forte, A. M.; Grand, S. P.

doi:10.1111/j.1365-246x.2009.04133.x

Cited by 210 publications

(333 citation statements)

References 81 publications

Supporting

Mentioning

295

Contrasting

Unclassified

Order By: Relevance

“…Below we discuss the effects of APM alone, buoyancy driven mantle flow alone, and full mantle convection from both APM and buoyancy driven flow. (Simmons et al 2009;Schmandt & Humphreys 2010, 2011Becker 2012), (c) HMSL-p06 (Houser et al 2008) and (d) SEMum (Lekić & Romanowicz 2011).…”

Section: F I N I T E S T R a I N A N D M A N T L E F L O W M O D E L mentioning

confidence: 99%

“…Four models are shown, calculated by subtracting the effects of density-buoyancy driven mantle flow (with no-slip boundary conditions) from a total model that has velocity boundary conditions of APM together with density-buoyancy driven mantle flow effects. APM effects computed from models that had density-buoyancy flow obtained from (a) model SAW642AN (Panning & Romanowicz 2006), (b) model SH11 TX2008 (Simmons et al 2009;Schmandt & Humphreys 2010, 2011Becker 2012), (c) model HMSL-p06 (Houser et al 2008) and (d) model SEMum (Lekić & Romanowicz 2011). Profile A-A shows location of cross-sections in Fig.…”

Section: F I N I T E S T R a I N A N D M A N T L E F L O W M O D E L mentioning

confidence: 99%

“…Becker et al 2003Becker et al , 2006. (Simmons et al 2009;Schmandt & Humphreys 2010, 2011Becker 2012), (c) model HMSL-p06 (Houser et al 2008) and (d) model SEMum (Lekić & Romanowicz 2011). Predicted anisotropy fast polarization directions together with SKS splitting directions (red vectors: this study; purple vectors: compiled by Becker et al 2012).…”

Section: T H E I N F L U E N C E O F P L At E M O T I O N a L O N Ementioning

confidence: 99%

“…11. (Simmons et al 2009;Schmandt & Humphreys 2010, 2011Becker 2012), (c) model HMSL-p06 (Houser et al 2008) and (d) model SEMum (Lekić & Romanowicz 2011). computed by first calculating the full mantle flow field (including effects of buoyancy driven mantle flow) with imposed surface boundary conditions of APM [HS3-NUVEL-1A (Gripp & Gordon 2002)], and then second by subtracting out the effects of buoyancyrelated flow alone, computed using no-slip boundary conditions. This procedure yields identical results for plate motion effects, regardless of which tomography model is used in the original full calculation of mantle flow (Figs 6 and 7).…”

Section: F I N I T E S T R a I N A N D M A N T L E F L O W M O D E L mentioning

confidence: 99%

See 3 more Smart Citations

Anisotropy from SKS splitting across the Pacific-North America plate boundary offshore southern California

Ramsay¹,

Kohler²,

Davis³

et al. 2016

Geophys. J. Int.

View full text Add to dashboard Cite

S U M M A R YSKS arrivals from ocean bottom seismometer (OBS) data from an offshore southern California deployment are analysed for shear wave splitting. The project involved 34 OBSs deployed for 12 months in a region extending up to 500 km west of the coastline into the oceanic Pacific plate. The measurement process consisted of removing the effects of anisotropy using a range of values for splitting fast directions and delay times to minimize energy along the transverse seismometer axis. Computed splitting parameters are unexpectedly similar to onland parameters, exhibiting WSW-ENE fast polarization directions and delays between 0.8 and 1.8 s, even for oceanic plate sites. This is the first SKS splitting study to extend across the entire boundary between the North America and Pacific plates, into the oceanic part of the Pacific plate. The splitting results show that the fast direction of anisotropy on the Pacific plate does not align with absolute plate motion (APM), and they extend the trend of anisotropy in southern California an additional 500 km west, well onto the oceanic Pacific plate. We model the finite strain and anisotropy within the asthenosphere associated with density-buoyancy driven mantle flow and the effects of APM. In the absence of plate motion effects, such buoyancy driven mantle flow would be NE-directed beneath the Pacific plate observations. The best-fit patterns of mantle flow are inferred from the tomography-based models that show primary influences from foundering higher-density zones associated with the history of subduction beneath North America. The new offshore SKS measurements, when combined with measurements onshore within the plate boundary zone, indicate that dramatic lateral variations in density-driven upper-mantle flow are required from offshore California into the plate boundary zone in California and western Basin and Range.

show abstract

Section: F I N I T E S T R a I N A N D M A N T L E F L O W M O D E L mentioning

confidence: 99%

Section: F I N I T E S T R a I N A N D M A N T L E F L O W M O D E L mentioning

confidence: 99%

Section: T H E I N F L U E N C E O F P L At E M O T I O N a L O N Ementioning

confidence: 99%

Section: F I N I T E S T R a I N A N D M A N T L E F L O W M O D E L mentioning

confidence: 99%

See 2 more Smart Citations

Anisotropy from SKS splitting across the Pacific-North America plate boundary offshore southern California

Ramsay¹,

Kohler²,

Davis³

et al. 2016

Geophys. J. Int.

View full text Add to dashboard Cite

show abstract

“…In brief, the elastic constants were created by Walker et al (2011) using the flow field of the TX2008 model of Simmons et al (2009) to produce strain histories at each point on a 5 • -by-5 • longitudelatitude grid, 100 km above the CMB. They used estimates of postperovskite (ppv) deformation mechanisms, to perform viscoplastic self-consistent modelling along these strain histories, yielding the texture of a wholly-ppv lowermost mantle.…”

Section: Geodynamically-derived Modelmentioning

confidence: 99%

The limits of ray theory when measuring shear wave splitting in the lowermost mantle withScSwaves

Nowacki¹,

Wookey

2016

Geophys. J. Int.

View full text Add to dashboard Cite

SUMMARYObservations of shear wave splitting provide unambiguous evidence of the presence of anisotropy in the Earth's lowermost mantle, a region known as D ′′ . Much recent work has attempted to use these observations to place constraints on strain above the core-mantle boundary (CMB), as this may help map flow throughout the mantle. Previously, this interpretation has relied on the assumption that waves can be modelled as infinite-frequency rays, or that the Earth is radially symmetric. Due to computational constraints it has not been possible to test these approximations until now. We use fully three-dimensional, generally-anisotropic simulations of ScS waves at the frequencies of the observations to show that ray methods are sometimes inadequate to interpret the signals seen. We test simple, uniform models, and for a D ′′ layer as thin as 50 km, significant splitting may be produced, and we find that recovered fast orientations usually reflect the imposed fast orientation above the CMB. Ray theory in these cases provides useful results, though there are occasional, notable differences between forward methods. Isotropic models do not generate apparent splitting. We also test more complex models, including ones based on our current understanding of mineral plasticity and elasticity in D ′′ . The results show that variations of anisotropy over even several hundred kilometres cause the ray-theoretical and finite-frequency calculations to differ greatly. Importantly, models with extreme mineral alignment in D ′′ yield splitting times not dissimilar to observations (δt ≤ 3 s), suggesting that anisotropy in the lowermost mantle is probably much stronger than previously thought-potentially ∼10 % shear wave anisotropy or more. We show that if the base of the mantle is as complicated as we believe, future studies of lowermost mantle anisotropy will have to incorporate finite-frequency effects to fully interpret observations of shear wave splitting.

show abstract

Mantle dynamics in the Mediterranean

et al. 2014

View full text Add to dashboard Cite

The Mediterranean offers a unique opportunity to study the driving forces of tectonic deformation within a complex mobile belt. Lithospheric dynamics are affected by slab rollback and collision of two large, slowly moving plates, forcing fragments of continental and oceanic lithosphere to interact. This paper reviews the rich and growing set of constraints from geological reconstructions, geodetic data, and crustal and upper mantle heterogeneity imaged by structural seismology. We proceed to discuss a conceptual and quantitative framework for the causes of surface deformation. Exploring existing and newly developed tectonic and numerical geodynamic models, we illustrate the role of mantle convection on surface geology. A coherent picture emerges which can be outlined by two, almost symmetric, upper mantle convection cells. The downwellings are found in the center of the Mediterranean and are associated with the descent of the Tyrrhenian and the Hellenic slabs. During plate convergence, these slabs migrated backward with respect to the Eurasian upper plate, inducing a return flow of the asthenosphere from the back-arc regions toward the subduction zones. This flow can be found at large distance from the subduction zones and is at present expressed in two upwellings beneath Anatolia and eastern Iberia. This convection system provides an explanation for the general pattern of seismic anisotropy in the Mediterranean, first-order Anatolia, and Adria microplate kinematics and may contribute to the high elevation of scarcely deformed areas such as Anatolia and eastern Iberia. More generally, the Mediterranean is an illustration of how upper mantle, small-scale convection leads to intraplate deformation and complex plate boundary reconfiguration at the westernmost terminus of the Tethyan collision.

show abstract

Joint seismic, geodynamic and mineral physical constraints on three-dimensional mantle heterogeneity: Implications for the relative importance of thermal versus compositional heterogeneity

Cited by 210 publications

References 81 publications

Anisotropy from SKS splitting across the Pacific-North America plate boundary offshore southern California

Anisotropy from SKS splitting across the Pacific-North America plate boundary offshore southern California

The limits of ray theory when measuring shear wave splitting in the lowermost mantle withScSwaves

Mantle dynamics in the Mediterranean

Contact Info

Product

Resources

About