Southwest Pacific Absolute Plate Kinematic Reconstruction Reveals Major Cenozoic Tonga‐Kermadec Slab Dragging

Lagemaat, Suzanna van de; Hinsbergen, Douwe J.J. van; Boschman, Lydian M.; Kamp, Peter J.J.; Spakman, Wim

doi:10.1029/2017tc004901

Cited by 45 publications

(54 citation statements)

References 139 publications

(314 reference statements)

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“…It would require, however, that the Agattu slab underwent~2,000 km of roll-back from its location of subduction initiation to its modern mantle position. Roll-back of such magnitude may well be possible, but dragging a slab over such a distance through the mantle may be unrealistic-although we note that >1,200 km of slab dragging was recently shown for the Tonga slab (van de Lagemaat et al, 2018). Also, the implied rate of roll-back in our model of~10 cm/year is very high.…”

Section: 1029/2018tc005164mentioning

confidence: 63%

“…We test our reconstruction against the presence of slabs in the mantle at locations predicted, although we may in places provide different interpretations than van der Meer et al (2018), in the light of our new reconstruction. We assume that, after breakoff from surface plates, slabs sink vertically (Domeier et al, 2016;van der Meer et al, 2010), but that during their subduction they may roll back, or be dragged forward or sideways through the mantle (e.g., Chertova et al, 2014;Funiciello et al, 2008;Schellart et al, 2008;Spakman et al, 2018;van de Lagemaat et al, 2018). We therefore test whether slabs are present in the mantle at locations where our model predicts their break-off, at depths consistent with globally determined sinking rates of~1-2 cm/year (Butterworth et al, 2014;van der Meer et al, 2010van der Meer et al, , 2018.…”

Section: Seismic Tomographic Constraintsmentioning

confidence: 99%

“…Other candidates to have accommodated inception of Pacific subduction around 50 Ma is subduction initiation at the Izu-Bonin-Marianas Trench (Faccenna et al, 2012;Ishizuka et al, 2011;Seton et al, 2015) and the Tonga-Kermadec Trench (e.g., Sutherland et al, 2017). However, as there was only very minor Pacific-Australia convergence before 45 Ma, and most if not all such convergence was accommodated at the New Caledonia-Northland subduction zone between the modern Tonga Trench and Australia until 30 Ma Tonga-Kermadec subduction initiation is kinematically quite unlikely to have happened long before 30 Ma (van de Lagemaat et al, 2018). Subduction initiation at the Izu-Bonin-Marianas Trench is widely considered to have started simultaneously with the inception of forearc spreading at 51 Ma (Ishizuka et al, 2011), but this critically hinges on the assumption that subduction initiation was a spontaneous event (Arculus et al, 2015;Stern, 2004;Stern et al, 2012).…”

Section: 1029/2018tc005164mentioning

confidence: 99%

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Reconstruction of Subduction and Back‐Arc Spreading in the NW Pacific and Aleutian Basin: Clues to Causes of Cretaceous and Eocene Plate Reorganizations

2019

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The Eocene (~50–45 Ma) major absolute plate motion change of the Pacific plate forming the Hawaii‐Emperor bend is thought to result from inception of Pacific plate subduction along one of its modern western trenches. Subduction is suggested to have started either spontaneously, or result from subduction of the Izanagi‐Pacific mid‐ocean ridge, or from subduction polarity reversal after collision of the Olyutorsky arc that was built on the Pacific plate with NE Asia. Here we provide a detailed plate‐kinematic reconstruction of back‐arc basins and accreted terranes in the northwest Pacific region, from Japan to the Bering Sea, since the Late Cretaceous. We present a new tectonic reconstruction of the intraoceanic Olyutorsky and Kronotsky arcs, which formed above two adjacent, oppositely dipping subduction zones at ~85 Ma within the north Pacific region, during another Pacific‐wide plate reorganization. We use our reconstruction to explain the formation of the submarine Shirshov and Bowers Ridges and show that if marine magnetic anomalies reported from the Aleutian Basin represent magnetic polarity reversals, its crust most likely formed in an ~85‐ to 60‐Ma back‐arc basin behind the Olyutorsky arc. The Olyutorsky arc was then separated from the Pacific plate by a spreading ridge, so that the ~55‐ to 50‐Ma subduction polarity reversal that followed upon Olyutorsky‐NE Asia collision initiated subduction of a plate that was not the Pacific. Hence, this polarity reversal may not be a straightforward driver of the Eocene Pacific plate motion change, whose causes remain enigmatic.

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Section: 1029/2018tc005164mentioning

confidence: 63%

Section: Seismic Tomographic Constraintsmentioning

confidence: 99%

Section: 1029/2018tc005164mentioning

confidence: 99%

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Reconstruction of Subduction and Back‐Arc Spreading in the NW Pacific and Aleutian Basin: Clues to Causes of Cretaceous and Eocene Plate Reorganizations

2019

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“…From Figure it follows that since 190 Ma, the Vizcaíno Peninsula (now at ~28°N) has been between 25°N and 35°N, implying that correlating the Mexican geological subduction records to mantle structure at these same latitudes is warranted. In Late Triassic to Early Jurassic time, the North American Plate moved ~15° to the north relative to the mantle (Figure ), which may imply that the oldest, Upper Triassic geological records of subduction (at the North American Plate) may be offset relative to deep mantle structure by such a distance, assuming that the slab did not undergo lateral dragging (Spakman et al, ), which may offset slabs relative to their initial position of subduction laterally by >10° (Van de Lagemaat et al, ). We also note that the TPW calculations of Steinberger and Torsvik () and Torsvik et al () include a mantle‐fixed TPW‐Euler pole that pierces through the centers of mass of the Large Low Shear wave Velocity Provinces at the core‐mantle boundary.…”

Section: Discussionmentioning

confidence: 99%

The Dynamic History of 220 Million Years of Subduction Below Mexico: A Correlation Between Slab Geometry and Overriding Plate Deformation Based on Geology, Paleomagnetism, and Seismic Tomography

Boschman

Hinsbergen

Kimbrough

et al. 2018

Geochem Geophys Geosyst

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Global tectonic reconstructions of pre‐Cenozoic plate motions rely primarily on paleomagnetic and geological data from the continents, and uncertainties increase significantly with deepening geological time. In attempting to improve such deep‐time plate kinematic reconstructions, restoring lost oceanic plates through the use of geological and seismic tomographical evidence for past subduction is key. The North American Cordillera holds a record of subduction of oceanic plates that composed the northeastern Panthalassa Ocean, the large oceanic realm surrounding Pangea in Mesozoic times. Here we present new paleomagnetic data from subduction‐related rock assemblages of the Vizcaíno Peninsula of Baja California, Mexico, which yield a paleolatitudinal plate motion history equal to that of the North American continent since Late Triassic time. This indicates that the basement rocks of the Vizcaíno Peninsula formed in the forearc of the North American Plate, adjacent to long‐lived eastward dipping subduction at the southern part of the western North American continental margin. Tomographic images confirm long‐lived, uninterrupted eastward subduction. We correlate episodes of overriding plate shortening and extension to flat and steep segments of the imaged slab. By integrating paleomagnetic, geological, and tomographic evidence, we provide a first‐order model that reconciles absolute North American plate motion and the deformation history of Mexico since Late Triassic time with modern slab structure.

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“…But the spatial correlation between ridge/plateau subduction and flat slab subduction has many exceptions, with regions of aseismic ridge subduction lacking flat slab subduction (e.g., Tonga with Louisville Ridge, New Hebrides with d'Entrecasteaux Ridge, Mariana with Marcus-Necker Ridge, Kamchatka with Emperor Ridge) and some flat slab subduction segments lacking an aseismic ridge/plateau (e.g., Mexico) Clayton, 2011, 2013;Manea et al, 2017). Others have proposed that flat slab subduction might result from forced trench retreat (e.g., van Hunen et al, 2004;Schepers et al, 2017), strong suction forces in the mantle wedge (e.g., Tovish et al, 1978), or slab-plume interaction (e.g., Betts et al, 2009). The latter mechanism has not generally been applied to Cenozoic examples of flat slab subduction, and recent geodynamic models of slabplume interaction for present-day Earth-like settings indicate that plumes generally do not affect slab geometry as their upward buoyancy flux can be more than two orders of magnitude smaller than the downward slab buoyancy flux (Mériaux et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Control of Subduction Zone Age and Size on Flat Slab Subduction

Schellart

2020

Front. Earth Sci.

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Flat slab subduction is an enigmatic style of subduction where the slab attains a horizontal orientation for up to several hundred kilometers below the base of the overriding plate. It has been linked to the subduction of buoyant aseismic ridges or plateaus, but the spatial correlation is problematic, as there are subducting aseismic ridges and plateaus that do not produce a flat slab, most notably in the Western Pacific, and there are flat slabs without an aseismic ridge or plateau. In this paper an alternative hypothesis is investigated which poses that flat slab subduction is associated with subduction zones that are both old (active for a long time) and wide (large trenchparallel extent). A global subduction zone compilation is presented showing that flat slabs preferentially occur at old (>∼80-100 Myr) and wide (≥∼6000 km) subduction zones. This is explained by the tendency for wide subduction zones to decrease their dip angle in the uppermost mantle with progressive time, especially in the center. A set of numerical subduction models confirms this behavior, showing that only the central parts of wide slabs progressively reduce their slab dip, such that slab flattening, and ultimately flat slab subduction, can occur. The models further show that a progressive decrease in slab dip angle for wide slabs leads to increased vertical deviatoric tensional stresses at the top surface of the slab (mantle wedge suction), facilitating flat slab subduction, while narrow slabs retain steep dip angles and low vertical deviatoric tensional stresses. The results provide a potential explanation why present-day flat slabs only occur in the Eastern Pacific, as only here subduction zones were old and wide enough to initiate flat slab subduction, and why Laramide flat slab subduction and South China flat slab subduction were possible in the geological past.

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Southwest Pacific Absolute Plate Kinematic Reconstruction Reveals Major Cenozoic Tonga‐Kermadec Slab Dragging

Cited by 45 publications

References 139 publications

Reconstruction of Subduction and Back‐Arc Spreading in the NW Pacific and Aleutian Basin: Clues to Causes of Cretaceous and Eocene Plate Reorganizations

Reconstruction of Subduction and Back‐Arc Spreading in the NW Pacific and Aleutian Basin: Clues to Causes of Cretaceous and Eocene Plate Reorganizations

The Dynamic History of 220 Million Years of Subduction Below Mexico: A Correlation Between Slab Geometry and Overriding Plate Deformation Based on Geology, Paleomagnetism, and Seismic Tomography

Control of Subduction Zone Age and Size on Flat Slab Subduction

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