the siwalik fold belt along the himalayan piedmont 10 km main frontal thrust main boundary thrust

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The Siwalik Fold Belt along the Himalayan piedmont 10 km Main Frontal Thrust Main Boundary Thrust

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The Siwalik Fold Belt along the Himalayan piedmont 10 km Main Frontal Thrust Main Boundary Thrust Slide 2 Structural Section Along Bagmati River. A Simple Fault Bend Fold. Slide 3 Uplifted Fluvial Terrace along Bagmati River. Strath surface Top of terrace tread Slide 4 Inferring paleo-river bed from terrace remnants 9.2 kaBP6.2 kaBP2.2 kaBP Slide 5 Slide 6 Slide 7 River incision and terrace formation across an active fold Slide 8 Folded abandoned terraces along Bagmati river Only the MFT is active along that section Incision rate correlates with the fold geometry suggesting that it reflects primarily tectonic uplift. Slide 9 The two major terrace T0 (9.2ka) and T3(2.2ka) show similar pattern of incision although their ratio is not exactly constant nore exactly equal to the ratio of their ages (0.19). Should incision be stationary if the fold is growing at a constant rate? Slide 10 Converting Incision into Uplift u(x,t): uplift relative to the undeformed footwall i(x,t): river incision b(t): sedimentation at front of the fold (local base level change) u(x,t)= i(x,t) + b Slide 11 Comparison of Uplift and Incision profiles The various terraces yield very similar uplift profiles. Slide 12 How do we convert that information into horizontal shortening of slip rate on the thrust fault? Uplift relative to footwall basement Slide 13 Determination of shortening from conservation of area Slide 14 Note that the excess area is a linear function of depth only if there is no backshear. (Bernard et al, 2006) Slide 15 It is assumed here that: - area is preserved during deformation (no compaction nor dilatancy) - deformation is plane (no displacement out of plane) Determination of shortening from conservation of area Slide 16 Relationships between fold shape and shortening depend on folding mechanism Fault-Bend Fold Detachment Fold Pure-shear Fault-Bend Fold Slide 17 Collocated proportional uplift Non-Collocated uplift Incremental deformation recorded by terraces or growth strata can be used to test fold models. (courtesy of John Suppe) Fault-Bend Fold Detachment Fold Slide 18 Constant bed length v1=v2 No backshearv1 constant with depth Constant bed thickness u(x) = v1.sin(x) Fault-bend folding Slide 19 Folded abandoned terraces along Bagmati river Is the uplift pattern consistent with Fault-bend Folding as has been assumed to construct the section? Slide 20 Comparing uplift derived from river incision with uplift predicted by fault-bend folding It is possible to estimate the cumulative shortening since the abandonment of each terrace. The uplift pattern is consistent with fold-bend folding with no back-shear. (Lave and Avouac, 2000) Slide 21 Comparing uplift derived from river incision with uplift predicted by fault-bend folding The shortening rate across the fold is estimated to 21 +/- 1.5 mm/yr (taking into account the fact that slip is probably stick slip) (Lave and Avouac, 2000) Slide 22 Constant bed length v1=v2 No backshearv1 constant with depth Constant bed thickness u(x) = v1.sin(x) Fault-bend folding