Imaging continental breakup using teleseismic body waves: The <scp>W</scp>oodlark <scp>R</scp>ift, <scp>P</scp>apua <scp>N</scp>ew <scp>G</scp>uinea

Eilon, Z.; Abers, G. A.; Gaherty, J. B.; Jin, Ge

doi:10.1002/2015gc005835

Cited by 39 publications

(98 citation statements)

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“…It could represent a remnant slab dipping either north or south, or some other sort of instability; given the broader setting, it is likely that this is a remnant of earlier Tertiary subduction. Teleseismic imaging [ Eilon et al , ] shows that the earthquakes lie inside an anomalously fast body consistent with such low temperatures, supporting the inference of a cold and possibly damp body just north of the rift axis.…”

Section: Discussionmentioning

confidence: 89%

“…The lithospheric mantle may have been removed from below by some combination of thermal and chemical erosion from upward percolating melts [ Holtzman and Kendall , ]. Low submoho velocities (Figure d) [ Jin et al , ] and high V P / V S ratios beneath the D'Entrecasteaux Islands [ Eilon et al , ] indicate the presence of small degrees of upper mantle melts (≤1%) or hydration that could contribute to lithospheric degradation. Jin et al [] also suggest the potential impact of felsic compositional heterogeneity in explaining the low velocities at lithospheric depth.…”

Section: Discussionmentioning

confidence: 99%

“…The axis of this low‐velocity mantle continues without break from the oceanic rift tip westward beneath the MCCs. It is bound sharply to the north by a high‐velocity low‐temperature mantle structure at depths less than 100 km beneath the Trobriand Platform [ Eilon et al , ; Jin et al , ]. The mantle shows anisotropic mantle fabrics similar to a mid‐ocean ridge with spreading‐parallel fast directions [ Eilon et al , ]; anisotropic body wave tomography shows that the spreading‐parallel fast directions lie within hot, asthenospheric mantle (Z. Eilon et al, A joint inversion for shear velocity and anisotropy: The Woodlark Rift, Papua New Guinea, submitted to Geophysical Journal International , 2015).…”

Section: Tectonics Of the Riftmentioning

confidence: 99%

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Southeast Papuan crustal tectonics: Imaging extension and buoyancy of an active rift

et al. 2016

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Southeast Papua hosts the world's youngest ultra‐high‐pressure (UHP) metamorphic rocks. These rocks are found in an extensional setting in metamorphic core complexes. Competing theories of extensional shear zones or diapiric upwelling have been suggested as driving their exhumation. To test these theories, we analyze the CDPAPUA temporary array of 31 land and 8 seafloor broadband seismographs. Seismicity shows that deformation is being actively accommodated on the core complex bounding faults, offset by transfer structures in a manner consistent with overall north‐south extension rather than radial deformation. Rayleigh wave dispersion curves are jointly inverted with receiver functions for crustal velocity structure. They show crustal thinning beneath the core complexes of 30–50% and very low shear velocities at all depths beneath the core complexes. On the rift flanks velocities resemble those of normal continents and increase steadily with depth. There is no evidence for velocity inversions that would indicate that a major density inversion exists to drive crustal diapirs. Also, low‐density melt seems minor within the crust. Together with the extension patterns apparent in seismicity, these data favor an extensional origin for the core complexes and limit the role of diapirism as a secondary exhumation mechanism, although deeper mantle diapirs may be undetected. A small number of intermediate‐depth earthquakes, up to 120 km deep, are identified for the first time just northeast of the D'Entrecasteaux Islands. They occur at depths similar to those recorded by UHP rocks and similar temperatures, indicating that the modern seismicity occurs at the setting that generates UHP metamorphism.

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Section: Discussionmentioning

confidence: 89%

Section: Discussionmentioning

confidence: 99%

Section: Tectonics Of the Riftmentioning

confidence: 99%

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Southeast Papuan crustal tectonics: Imaging extension and buoyancy of an active rift

et al. 2016

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“…The tectonic regime in SE Papua New Guinea is governed by the oblique‐convergent motion of the Pacific Plate (PAC) relative to the Australian Plate (AUS) creating a complex array of microplates in the collision zone (Figure ; Tregoning et al, ; Wallace et al, , ). The Woodlark‐Solomon Sea microplate rotates counterclockwise relative to the Australian plate about a nearby Euler pole resulting in a north‐south opening of the Woodlark Basin with extension rates increasing to the east (Eilon et al, ; Taylor et al, ; Wallace et al, ). In the east, seafloor spreading has occurred at rates >20–60 mm/year since ~6 Ma, as recorded by magnetic anomalies in the Woodlark Basin (Taylor et al, ).…”

Section: Tectonic and Geological Setting Of The Mai'iu Faultmentioning

confidence: 99%

Structural and Geomorphic Evidence for Rolling‐Hinge Style Deformation of an Active Continental Low‐Angle Normal Fault, SE Papua New Guinea

et al. 2019

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To what degree low‐angle normal faults (LANFs) deform by a “rolling‐hinge” mechanism is still debated for continental metamorphic core complexes (MCCs). The Mai'iu fault in SE Papua New Guinea is one of the best preserved and fastest slipping active continental LANFs on Earth, providing an ideal setting in which to evaluate footwall deformation and doming in MCCs. We analyzed structural field data from the exhumed slip surface and subjacent footwall of the Mai'iu fault, together with geomorphic data interpreted from aerial photographs and GeoSAR‐derived digital terrain models. The exhumed part of the Mai'iu fault forms a smooth, continuous surface, traced at least 28 km in the slip direction. The fault emerges from the ground near sea level with a northward dip of ≤22°N and flattens southward over the crest of the Suckling‐Dayman Dome. Its most southern mapped portion dips ~12°S. Geomorphic and structural evidence indicates updip tectonic transport of the footwall and progressive back‐tilting of the exposed part of the fault and the underlying foliation through >26°. We infer that antithetic (northside‐up) dip slip on an array of steep‐dipping faults striking parallel to the Mai'iu fault accommodated some of the exhumation‐related inelastic bending of the footwall. The exhuming footwall was subject to late‐stage slip‐parallel contractional strain as recorded by a postmetamorphic crenulation foliation that strikes parallel to the curved Mai'iu fault trace, by folds of bedding in a large rider block that is stranded on the current footwall and by strike‐parallel warps in the exhumed fault surface. Geodynamic modeling predicts the observed footwall strain.

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“…Seismic surface wave and body wave tomographic studies, using newly collected data, show that the crust and lithosphere under the islands is thinner than is inferred for the Papuan Peninsula [ Abers et al ., ; Eilon et al ., ]. The ∼50 to 100 km wide zone of low velocities extends from the base of the crust down to at least 100 km depth [ Eilon et al ., ]. The thin crust under the islands implies that the high average elevation of the islands is likely supported by hot, low‐density mantle asthenosphere.…”

Section: Introductionmentioning

confidence: 99%

Eduction, extension, and exhumation of ultrahigh‐pressure rocks in metamorphic core complexes due to subduction initiation

Petersen

Buck

2015

Geochem Geophys Geosyst

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The controversy over the exhumation of ultrahigh-pressure (UHP) rocks centers on whether it involves rising of pieces of crust detached from subducted continental lithosphere or an entire subducted plate that undergoes ''eduction,'' i.e., reverse subduction. We present a new thermomechanical model of continental subduction showing that these apparently contrasting mechanisms can occur together: crust subducted deep enough is heated and weakened, causing limited diapiric rise, while crust subducted to shallower depths retains strength and is exhumed only by eduction. The model also shows for the first time how eduction followed by seafloor spreading can occur in a zone of regional convergence. This occurs spontaneously when subduction of buoyant crust causes a subduction zone to ''lock up'' in one place causing a new subduction zone to form in another. The model is consistent with many features of the youngest region of UHP rock exhumation on earth: the D'Entrecasteaux Islands. UHP exhumation and the amount of regional extension, as well as the seismic structure around the islands, can be explained by eduction. Ductile flow fabrics, seen on the islands, would result from exhumation of the most deeply subducted crust heated enough to undergo partial melting. Reversal of motion on the north-dipping continental subduction zone, required by this model, was likely triggered by initiation of the New Britain Trench, as suggested previously. Our model implies that the crust of Goodenough Basin, south of the islands, was exhumed by eduction in the last 5 Ma and this hypothesis can be tested by drilling.

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Imaging continental breakup using teleseismic body waves: The Woodlark Rift, Papua New Guinea

Cited by 39 publications

References 84 publications

Southeast Papuan crustal tectonics: Imaging extension and buoyancy of an active rift

Southeast Papuan crustal tectonics: Imaging extension and buoyancy of an active rift

Structural and Geomorphic Evidence for Rolling‐Hinge Style Deformation of an Active Continental Low‐Angle Normal Fault, SE Papua New Guinea

Eduction, extension, and exhumation of ultrahigh‐pressure rocks in metamorphic core complexes due to subduction initiation

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