Intra- and intertrench variations in flexural bending of the Manila, Mariana and global trenches: implications on plate weakening in controlling trench dynamics

Zhang, Fan; Lin, Jian; Zhou, Zhiyuan; Yang, Hongfeng; Wang, Zhan

doi:10.1093/gji/ggx488

Cited by 36 publications

(12 citation statements)

References 56 publications

(89 reference statements)

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“…Highest T ES estimates are found for sections 3, 9, and 20, 21, and 22. The reduction in elastic thickness from seaward of profile to trenchward for each section is found to be varying significantly along the trench with up to 60% reduction at section 9 and a significant reduction of around 50% at most regions along the trench similar to the values observed by Zhang et al () and almost no reduction at section 16 (Figure d). The distance at which the change in elastic thickness happens along the profile, which is associated with predominant normal faulting along the profile is found to be ~40–70 km all along the trench.…”

Section: Resultssupporting

confidence: 85%

Flexural Analysis Along the Sunda Trench: Bending, Buckling and Plate Coupling

2018

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The bathymetry and free-air gravity data offshore Sunda trench are used here to analyze the flexural forebulge and bending moment variations along the Southeast Asian subduction zone. The observed bathymetry is corrected for various effects such as the sediment loading, lithosphere age, and the gravity-derived isostatically compensated topography, which gave rise to the flexural deformation surface of the subducting Indo-Australian plate. From this, 28 across-trench sections were constructed to model the plate flexural bending along the Sunda trench. We observed that except in the northern Sumatra trench, rest of the Sunda trench is in agreement with the flexural model explained by the bending moment applied by the slab. In the northern Sumatra part of the trench, additional horizontal stresses of~30-40 MPa are required for better match of the flexural forebulge thereby increasing the coupling with the upper plate. The outcome of this analysis in comparison with the slab depth variation, which abruptly reduces from~600 km in Java to~200 km toward northern Sumatra, suggests that very large bending moment and horizontal stresses are anticorrelated with the slab depth. The shorter slab in Sumatra does not effectively pull the incoming plate in the mantle, and therefore, plate convergence is accommodated at shallow depth, increasing the coupling with the upper plate. We propose that horizontal stresses are the result of the lateral propagation of the stronger slab pull from the neighboring deeper southeastern Java slab.

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Section: Resultssupporting

confidence: 85%

Flexural Analysis Along the Sunda Trench: Bending, Buckling and Plate Coupling

2018

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“…The convergence between the Pacific and Philippine Sea plates is approximately orthogonal to the E‐W trench in the southernmost Mariana margin, which differs significantly from the mostly N‐S trend of the IBM arc (Figure ; Bird, ). In the southernmost Mariana, the trench reaches the deepest point on Earth at the Challenger Deep, which is subjected to the greatest tectonic loading and bending (Zhang et al, , ). This region lacks a well‐defined arc and is characterized by spatially distributed forearc segments that are separated from the Mariana forearc farther north (Figure ; Martinez et al, ; Ribeiro et al, ).…”

Section: Geological Settingmentioning

confidence: 99%

Deep Seismic Structure Across the Southernmost Mariana Trench: Implications for Arc Rifting and Plate Hydration

et al. 2019

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The southernmost Mariana margin lacks a mature island arc and thus differs significantly from the central-north Mariana and Izu-Bonin margins. This paper presents a new P wave velocity model of the crust and uppermost mantle structure based on a 349-km-long profile of wide-angle reflection/refraction data. The active source seismic experiment was conducted from the subducting Pacific plate to the overriding Philippine plate, passing through the Challenger Deep. The subducting plate has an average crustal thickness of~6.0 km with Vp of 7.0 ± 0.2 km/s at the base of the crust and low values of only 5.5-6.9 km/s near the trench axis. The uppermost mantle of the subducting plate is characterized by low velocities of 7.0-7.3 km/s. The overriding plate has a maximum crustal thickness of~18 km beneath the forearc with Vp of~7.4 km/s at the crustal bottom and 7.5-7.8 km/s in the uppermost mantle. A zone of slight velocity reduction is imaged beneath the Southwest Mariana Rift that is undergoing active rifting. The observed significant velocity reduction in a near-trench crustal zone of~20-30 km in the subducting plate is interpreted as a result of faulting-induced porosity changes and fracture-filling fluids. The velocity reduction in the uppermost mantle of both subducting and overriding plates is interpreted as mantle serpentinization with fluid sources from dehydration of the subducting plate and/or fluid penetration along faults.Plain Language Summary The southernmost Mariana margin is a convergence margin that lacks a mature island arc. The trench reaches the deepest point on Earth at the Challenger Deep, the origin of which is still little known. We acquired and analyzed new active source wide-angle reflection/refraction seismic data along a profile across the Challenge Deep, obtaining a new model of crustal and uppermost mantle velocity structure of both the subducting Pacific and overriding Philippine Sea plates. Significant velocity reduction is observed in the crust of the subducting plate, especially in a 20-to 30-km-wide zone near the trench axis, which is interpreted as a result of faulting-induced porosity changes and fracture-filling fluids. A zone of slight velocity reduction is imaged beneath the tectonically active Southwest Mariana Rift. Significant velocity reduction is also observed in the uppermost mantle of both subducting and overriding plates and is interpreted as a result of mantle serpentinization.

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“…Our analysis is similar to the global compilation by Levitt & Sandwell (1995) and later work by Bry & White (2007) but with a few significant differences, foremost of which is that those studies used constant-rigidity thin plate flexure to model gravity and topography profiles. Meanwhile, recent efforts that attempted to improve upon them by developing methods for variable-rigidity plates instead (Hunter & Watts 2016;Zhang et al 2017) are more closely related to our study, however, we will also mention some important distinctions in the details further below. The Levitt & Sandwell (1995) study limited the bathymetry to actual soundings while the Bry & White (2007) used actual soundings averaged over 710 E.S.M.…”

Section: Introductionmentioning

confidence: 99%

“…This is in contrast to some previous approaches in which the variable elastic thickness of a plate is represented with discontinuous regions of constant thickness, or a 'stair-step' form. Such stair-step variations in elastic thickness have been applied to modelling of trench-perpendicular profiles of bathymetry along the Chile (Contreras-Reyes & Osses 2010) and Mariana (Zhang et al 2014) subduction zones, as well as for a selection of subduction zones globally (Zhang et al 2017). In another study comparing the strength of the incoming plate across multiple trenches, ensemble average profiles of marine gravity anomalies within regions of and across entire circum-Pacific subduction zones were used as inputs for inverse modelling to obtain models of ramplike variations of elastic thickness (Hunter & Watts 2016).…”

Section: Introductionmentioning

confidence: 99%

Outer trench slope flexure and faulting at Pacific basin subduction zones

Garcia

Sandwell

Bassett

2019

Geophysical Journal International

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SUMMARY Flexure and fracturing of the seafloor on the outer trench wall of subduction zones reflect bending of the lithosphere beyond its elastic limit. To investigate these inelastic processes, we have developed a full nonlinear inversion approach for estimating the bending moment, curvature and outer trench wall fracturing using shipboard bathymetry and satellite altimetry-derived gravity data as constraints. Bending moments and downward forces are imposed along curved trench axes and an iterative method is used to calculate the nonlinear response for 26 sites in the circum-Pacific region having seafloor age ranging from 15 to 148 Ma. We use standard thermal and yield strength envelope models to develop the nonlinear moment versus curvature relationship. Two coefficients of friction of 0.6 and 0.3 are considered and we find that the lower value provides a better overall fit to the data. The main result is that the lithosphere is nearly moment saturated at the trench axis. The effective elastic thickness of the plate on the outer trench slope is at least three times smaller than the elastic thickness of the plate before bending at the outer rise in agreement with previous studies. The average seafloor depth of the unbent plate in these 26 sites matches the Parsons & Sclater depth versus age model beyond 120 Ma. We also use the model to predict the offsets of normal faults on the outer trench walls and compare this with the horst and graben structures observed by multibeam surveys. The model with the lower coefficient of friction fits the fault offset data close to the trench axis. However, the model predicts significant fracturing of the lithosphere between 75 and 150 km away from the trench axis where no fracturing is observed. To reconcile these observations, we impose a thermoelastic pre-stress in the lithosphere prior to subduction. This pre-stress delays the onset of fracturing in better agreement with the data.

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Intra- and intertrench variations in flexural bending of the Manila, Mariana and global trenches: implications on plate weakening in controlling trench dynamics

Cited by 36 publications

References 56 publications

Flexural Analysis Along the Sunda Trench: Bending, Buckling and Plate Coupling

Flexural Analysis Along the Sunda Trench: Bending, Buckling and Plate Coupling

Deep Seismic Structure Across the Southernmost Mariana Trench: Implications for Arc Rifting and Plate Hydration

Outer trench slope flexure and faulting at Pacific basin subduction zones

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