AV整氈窒

 

Karen Simon

ES_John_Doe_210H-214W

M.Sc. Thesis

Dynamical Modelling of Lithospheric Extension and Small-Scale Convection: Implications for Magmatism during the Formation of Volcanic Rifted Margins

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Enhanced melt productivity delivered by buoyant upwelling and small-scale convection of the mantle during rifting may play an important role in determining the fundamental structure of igneous crust produced during and following continental breakup. This thesis investigates the relationship between rift-related decompression melting and the influence of small-scale mantle convection and rift geometry on the subsequent production and distribution of melt-related crust. A two-dimensional plane-strain finite element method for viscous-plastic creeping flows is used to numerically model extension of the lithosphere. The evolving temperature and pressure fields within the model are coupled to an algorithm for predicting the amount and timing of decompression melting of upwelling mantle. Predicted melt fractions are converted to equivalent thicknesses of igneous crust, and the predicted crustal thicknesses for a series of models are compared to the observed crustal structure of rifted margins inferred from seismic data. Reference models characterized by passive plate-driven flow predict stable formation of ~7 km thick igneous crust. Models characterized by small-scale mantle convection can to first order reproduce the general architecture of most volcanic rifted margins, that is, a relatively narrow band of thick (12-13 km) igneous crust (inferred to occur along strike of the margin), juxtaposed with thinner oceanic crust farther offshore. The variability in thickness (4-7 km) predicted for the later-stage thinner igneous crust is however difficult to reconcile with global observations of oceanic crustal thickness (7-1 km). Also, the peak 13 km thickness of igneous crust predicted for models with convectively enhanced upwelling fails to match the great thicknesses (_>_20 km) of igneous crust observed at many volcanic margins; a small increase to mantle potential temperature appears necessary to predict generation of such thick igneous crust. Composite models that include both small-scale convection and an increase to mantle potential temperature predict large pulses in initial magmatism and generation of 17-21 km thick crust, followed by unstable production of thinner igneous crust. The results indicate that models with small-scale convection and no temperature anomaly may play a role in explaining the formation of volcanic margins with only moderately thick (11-15 km) igneous crust. Further, convection coupled with small increases to mantle temperature may be important during the initial phase of very thick igneous crust generation at some volcanic margins. The geometry of the lithosphere during extension appears to influence only moderately the spatial distribution of produced igneous crust. Predicted distributions of igneous crust are only weakly sensitive to asymmetric rifting of the lithosphere; this suggests that symmetry in the thermal structure of the upwelling sublithospheric mantle is the dominant control on the final distribution of igneous crust produced during rifting.

Keywords:
Pages: 72
Supervisor: Chris Beaumont