The Geometry of the Subducted Slab Beneath Sumatra Revealed by Regional and Teleseismic Traveltime Tomography

Liu, Shaolin; Suardi, I Dewa Putu Oka; Xu, Xiwei; Yang, Shuxin; Tong, Ping

doi:10.1029/2020jb020169

Cited by 21 publications

(14 citation statements)

References 94 publications

(386 reference statements)

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“…These dip direction estimates agree well with the Slab2 model (Figures 6 and 7). The continuous variation of slab dip direction along the Sunda trench (Figure 7c) implies slab folding or tearing, also noted in travel time tomography studies (Liu et al, 2019(Liu et al, , 2021. The slab folding may be a result of the oblique subduction of the Australian plate (Liu et al, 2019;McCaffrey, 2009), or the lateral bending of the Australian plate, which is increasingly driven by gravity on the east side of the Wharton fossil ridge as the plate cools down.…”

Section: Slab Internal Deformationmentioning

confidence: 74%

A New Method to Estimate Slab Dip Direction Using Receiver Functions and Its Application in Revealing Slab Geometry and a Diffuse Plate Boundary Beneath Sumatra

et al. 2023

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While dip direction is a fundamental parameter of slab geometry, it is rarely estimated quantitatively. Here, we develop a new method, Dip Direction Searching (DDS), of receiver functions (RFs) that reduces the uncertainty of slab dip direction estimation from tens to several degrees. DDS can also resolve the thickness and depth of a dipping structure. We then apply DDS to the RFs in the Sumatran subduction zone. Travel time differences of the converted phases from the upper and lower (oceanic Moho) boundaries of the dipping low‐velocity layer (LVL) along the plate interface show a thickness of 10–14 km. The results also show increased dip direction of the slab Moho from 47 ± 5.3° in southern Sumatra to 70 ± 10.7° in northern Sumatra, indicating a complicated slab geometry and internal deformation along strike. Similar dip directions are obtained for the upper and lower LVL boundaries beneath Nias and Enggano forearc islands in the north and south, whereas we find a larger discrepancy of ∼14–23° beneath Siberut and Pagai in between. The thicker LVL with a non‐negligible difference in the dip directions of its upper and lower bounds in the center of Sumatra is interpreted as a partially serpentinized mantle layer above the oceanic crust, forming a distinct channel atop the subducting slab. Our results provide basic observational constraints on the structure and geometry of the oceanic slab and associated subduction processes. Both synthetics and data analyses also indicate DDS can be applied in other subduction zones and for other dipping interfaces.

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Section: Slab Internal Deformationmentioning

confidence: 74%

A New Method to Estimate Slab Dip Direction Using Receiver Functions and Its Application in Revealing Slab Geometry and a Diffuse Plate Boundary Beneath Sumatra

et al. 2023

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“…An important clue is the low‐V zone in the subducted slab beneath Nias Island ( L4 in Figures 10a, 10b, and 11), which is confirmed by our extensive resolution tests (Figures 6c and 6d). Previous studies have suggested the presence of an intra‐slab low‐V zone caused by slab tearing under Toba (Hall & Spakman, 2015; Kong et al., 2020; Liu et al., 2021; Toyokuni et al., 2022), implying a somewhat extensive feature. In contrast, the low‐V anomaly L4 appears as an approximate cylinder with a diameter of ∼3° connecting the subslab mantle with the mantle wedge.…”

Section: Resultsmentioning

confidence: 94%

“…Previous tomographic studies in this region have unveiled the main features of the crust and upper mantle (e.g., Hall & Spakman, 2015;Liu et al, 2021;Toyokuni et al, 2022;Wang, Liu, et al, 2022). However, their low resolution prevented adequate imaging of the detailed structures.…”

Section: Tomographic Images and Tectonic Implicationsmentioning

confidence: 99%

“…Previous 3‐D tomographic models of North Sumatra have relatively low resolution, thus providing weak evidence for the slab tearing (Hall & Spakman, 2015; Widiyantoro & van der Hilst, 1997). A recent tomographic study used travel times of local and teleseismic events recorded at 57 stations to investigate the velocity structure beneath the North Sumatra region (Liu et al., 2021). However, their station coverage was still too sparse to capture the fine details of slab tearing beneath the Toba caldera.…”

Section: Introductionmentioning

confidence: 99%

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A Slab Window Beneath North Sumatra Revealed by P‐Wave Mantle Tomography

Zhao

Lin

et al. 2023

JGR Solid Earth

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Passive seismic studies have suggested that slab tearing occurs beneath North Sumatra, albeit the slab morphology is somewhat poorly constrained. The lack of resolution on the slab means that the presence of a tear has not been validated, and that the main factors responsible for slab tearing are hard to discern. We use a large seismic data set to determine a new 3‐D high‐resolution tomographic model of the crust and upper mantle beneath North Sumatra, which reveals a well‐defined low‐velocity channel that cuts across the subducting slab through a cavity. This feature cannot be reconciled with a tear in the slab, as previously suggested. Our relocated earthquakes exhibit a protruding cluster of seismicity along the subducted Investigator Fracture Zone, indicating that the high reliefs of the Investigator Fracture Zone possibly enhance the coupling between the subducted slab and the overriding plate. Shear stress resulting from the differential coupling in the slab may have created an area of mechanical weakness in correspondence of the fossil‐spreading ridges, which eventually led to the formation of a slab window. This window allows the exchange of mantle material from the subslab region up to the Toba volcano. We propose that the previously damaged parts (e.g., fracture zones and spreading centers) of the oceanic plate could help promote the growth of a slab window.

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“…We use the teleseismic imaging method based on the eikonal equation to invert the crust-mantle velocity and the radial anisotropy model. The eikonal equation in any heterogeneous medium can be expressed as (Liu et al, 2021):…”

Section: Methodsmentioning

confidence: 99%

P-wave velocity and radial anisotropy beneath Sichuan-Yunnan area revealed by teleseismic traveltime tomography

Tang

Wang

Wen

et al. 2022

Preprint

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The Sichuan-Yunnan area is located on the southeastern margin of the Tibet Plateau, and it interacts with the Tibet Plateau because of the the southeastward motion of the plateau material since the Cenozoic. Therefore, the Sichuan-Yunnan area acts an important window to understand the uplift and deformation processes of the largest and highest plateau in the world. In this study, we invert the teleseismic relative traveltime differentials extracted from waveform cross-correction to invert the P-wave and radial anisotropy (RAN) beneath the Sichuan-Yunnan area. In the tomographic inversion, we utilize an eikonal equation-based tomography method, and obtain the subsurface P-wave velocity and radial anisotropic structure down to a depth of 700 km. Our P-wave tomography results show that high-velocity anomalies are beneath Sichuan basin at depths from ~ 30 km to ~ 200 km, and remarkable low-velocity anomalies south of Sichuan basin are below the Xiaojiang fault and Red River fault at the same depths. Notably, low-velocity anomalies west of Sichuan basin are under the Songpan-Ganzi block at depths less than 200 km. In addition, our tomography results do not reveal high-velocity anomalies in the mantle transition zone (MTZ) beneath Xiaojiang fault. Evidently, the lithosphere of Sichuan basin exhibits negative radial anisotropy, and the Emeishan large igneous province shows visible negative radial anisotropy. Remarkably, positive radial anisotropy is found underneath Red River fault and it extends a depth of at least 170 km.

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The Geometry of the Subducted Slab Beneath Sumatra Revealed by Regional and Teleseismic Traveltime Tomography

Cited by 21 publications

References 94 publications

A New Method to Estimate Slab Dip Direction Using Receiver Functions and Its Application in Revealing Slab Geometry and a Diffuse Plate Boundary Beneath Sumatra

A New Method to Estimate Slab Dip Direction Using Receiver Functions and Its Application in Revealing Slab Geometry and a Diffuse Plate Boundary Beneath Sumatra

A Slab Window Beneath North Sumatra Revealed by P‐Wave Mantle Tomography

P-wave velocity and radial anisotropy beneath Sichuan-Yunnan area revealed by teleseismic traveltime tomography

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