Slabs in the lower mantle and their modulation of plume formation

Tan, Eh; Gurnis, Michael; Han, Lei

doi:10.1029/2001gc000238

Cited by 148 publications

(132 citation statements)

References 60 publications

Supporting

Mentioning

123

Contrasting

Order By: Relevance

“…Perhaps some type of SPO such as oriented melt inclusions is required to explain the complex anisotropy observed in the central Pacific. Another explanation is based on the hypothesis that slabs induce upwellings at the base of the mantle [Tan et al, 2002]. Because of the sluggish decay of preexisting fabric the laterally oriented strain may turn to vertical in the upwellings.…”

Section: Discussionmentioning

confidence: 99%

Development of finite strain in the convecting lower mantle and its implications for seismic anisotropy

2003

View full text Add to dashboard Cite

[1] Seismological observations have revealed patches of seismic anisotropy in regions related to mantle upwelling and paleosubduction within an otherwise isotropic lower mantle. A combination of numerical modeling and mineral physics is used to constrain the source of anisotropy in these regions in an effort to better understand lower mantle dynamics and mineral physics. Specifically, it is investigated whether lattice-preferred orientation (LPO) can explain the anisotropy observed in regions of paleosubduction. Since LPO is caused by dislocation creep and is destroyed by diffusion creep, we can develop deformation mechanism maps to determine which regions allow for the development of a mineral fabric. Strain is then calculated in these regions and is related to mineral physics experiments combined with high-pressure elastic constants of lower mantle minerals in order to assess the predicted seismic anisotropy. Uncertainties in rheological parameters such as the transition stress between dislocation creep and diffusion creep necessitate a full evaluation of the parameter range. The effect of variations in transition stress, activations parameters, and strength of slabs on fabric development is investigated. It is shown that LPO is a likely candidate for the cause of lowermost mantle anisotropy in regions of paleosubduction.

show abstract

Section: Discussionmentioning

confidence: 99%

Development of finite strain in the convecting lower mantle and its implications for seismic anisotropy

2003

View full text Add to dashboard Cite

show abstract

“…The heat transferred to the lowermost mantle is then trapped beneath the cold slabs which, because of their high viscosity must be conductively heated. The consequence is a long term build-up of heat beneath the slabs that eventually gives rise to a superplume event [68]. If all the oceanic lithosphere subducted during the transit of the Cache Creek seamounts sank to the Core Mantle Boundary, the result would have been the development, between 280 Ma and 150 Ma, of a substantial slab blanket on the sub-Pacific portion of the core (Fig.…”

Section: Panthalassamentioning

confidence: 99%

“…7). Thermal modeling of subducted slabs [68] suggests that they can penetrate intact to the core-mantle boundary where they would give rise to "normal" hotspots along the edges of the slabs. Blanketing of the core-mantle boundary by subducted slabs is interpreted to result in an increased temperature gradient at the core-mantle boundary, resulting in increased heat transfer from the core to the mantle.…”

Section: Panthalassamentioning

confidence: 99%

The odyssey of the Cache Creek terrane, Canadian Cordillera: Implications for accretionary orogens, tectonic setting of Panthalassa, the Pacific superwell, and break-up of Pangea

Johnston

Borel²

2007

Earth and Planetary Science Letters

View full text Add to dashboard Cite

The Cache Creek terrane (CCT) of the Canadian Cordillera consists of accreted seamounts that originated adjacent to the Tethys Ocean in the Permian. We utilize Potential Translation Path plots to place quantitative constraints on the location of the CCT seamounts through time, including limiting the regions within which accretion events occurred. We assume a starting point for the CCT seamounts in the easternmost Tethys at 280 Ma. Using reasonable translation rates (11 cm/a), accretion to the StikiniaQuesnellia oceanic arc, which occurred at about 230 Ma, took place in western Panthalassa, consistent with the mixed Tethyan fauna of the arc. Subsequent collision with a continental terrane, which occurred at about 180 Ma, took place in central Panthalassa, N 4000 km west of North America yielding a composite ribbon continent. Westward subduction of oceanic lithosphere continuous with the North American continent from 180 to 150 Ma facilitated docking of the ribbon continent with the North American plate.The paleogeographic constraints provided by the CCT indicate that much of the Canadian Cordilleran accretionary orogen is exotic. The accreting crustal block, a composite ribbon continent, grew through repeated collisional events within Panthalassa prior to docking with the North American plate. CCT's odyssey requires the presence of subduction zones within Panthalassa and indicates that the tectonic setting of the Panthalassa superocean differed substantially from the current Pacific basin, with its central spreading ridge and marginal outward dipping subduction zones. A substantial volume of oceanic lithosphere was subducted during CCT's transit of Panthalassa. Blanketing of the core by these cold oceanic slabs enhanced heat transfer out of the core into the lowermost mantle, and may have been responsible for the Cretaceous Normal Superchron, the coeval Pacific-centred mid-Cretaceous superplume event, and its lingering progeny, the Pacific Superswell. Far field tensile stress attributable to the pull of the slab subducting beneath the ribbon continent from 180 to 150 Ma instigated the opening of the Atlantic, initiating the dispersal phase of the supercontinent cycle by breaking apart Pangea. Docking of the ribbon continent with the North American plate at 150 Ma terminated the slab pull induced stress, resulting in a drastic reduction in the rate of spreading within the growing Atlantic Ocean.

show abstract

“…In isochemical models, plume roots commonly locate near the edges of slabs [Lenardic and Kaula, 1994;Lowman and Jarvis, 1996;Tan et al, 2002], which have strong lateral temperature gradients at the CMB. However, in thermochemical models, plumes are more likely to root on crests of the chemical anomalies McNamara and Zhong, 2005;Deschamps and Tackley, 2009].…”

Section: Introductionmentioning

confidence: 99%

On the location of plumes and lateral movement of thermochemical structures with high bulk modulus in the 3-D compressible mantle

Tan

Leng

Zhong

et al. 2011

Geochem. Geophys. Geosyst.

Self Cite

109

102

View full text Add to dashboard Cite

[1] The two large low shear velocity provinces (LLSVPs) at the base of the lower mantle are prominent features in all shear wave tomography models. Various lines of evidence suggest that the LLSVPs are thermochemical and are stable on the order of hundreds of million years. Hot spots and large igneous province eruption sites tend to cluster around the edges of LLSVPs. With 3-D global spherical dynamic models, we investigate the location of plumes and lateral movement of chemical structures, which are composed of dense, high bulk modulus material. With reasonable values of bulk modulus and density anomalies, we find that the anomalous material forms dome-like structures with steep edges, which can survive for billions of years before being entrained. We find that more plumes occur near the edges, rather than on top, of the chemical domes. Moreover, plumes near the edges of domes have higher temperatures than those atop the domes. We find that the location of the downwelling region (subduction) controls the direction and speed of the lateral movement of domes. Domes tend to move away from subduction zones. The domes could remain relatively stationary when distant from subduction but would migrate rapidly when a new subduction zone initiates above. Generally, we find that a segment of a dome edge can be stationary for 200 million years, while other segments have rapid lateral movement. In the presence of time-dependent subduction, the computations suggest that maintaining the lateral fixity of the LLSVPs at the core-mantle boundary for longer than hundreds of million years is a challenge.

show abstract

Slabs in the lower mantle and their modulation of plume formation

Cited by 148 publications

References 60 publications

Development of finite strain in the convecting lower mantle and its implications for seismic anisotropy

Development of finite strain in the convecting lower mantle and its implications for seismic anisotropy

The odyssey of the Cache Creek terrane, Canadian Cordillera: Implications for accretionary orogens, tectonic setting of Panthalassa, the Pacific superwell, and break-up of Pangea

On the location of plumes and lateral movement of thermochemical structures with high bulk modulus in the 3-D compressible mantle

Contact Info

Product

Resources

About