Kinematics of Late Cretaceous subduction initiation in the Neo‐Tethys Ocean reconstructed from ophiolites of Turkey, Cyprus, and Syria

Maffione, Marco; Hinsbergen, Douwe J.J. van; Gelder, Gino de; Goes, Freek C. van der; Morris, Antony

doi:10.1002/2016jb013821

Cited by 89 publications

(88 citation statements)

References 163 publications

(281 reference statements)

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“…Eocene plate motion change is contemporaneous with the initiation of major new intraoceanic subduction zones across a wide region of the western Pacific presently represented by the Izu-Bonin-Mariana and Tonga-Kermadec systems (Gurnis et al, 2004). The details of earlier subduction initiations are less clear, but mid-Cretaceous subduction initiation within the Tethys ocean (Guilmette et al, 2018;Maffione et al, 2017) could be connected to increases in rift velocity within the South Atlantic and between Australia and Antarctica. Our model results allow us to propose the far-field effect of rift acceleration and breakup in the North Atlantic and Eurasia Basin (∼55 Myr ago) as an alternative, plausible catalyst for distal, almost contemporaneous changes in plate boundary configuration and force balance.…”

Section: Discussionmentioning

confidence: 99%

Breakup Without Borders: How Continents Speed Up and Slow Down During Rifting

Ulvrová

Brune

Williams

2019

Geophysical Research Letters

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Relative plate motions during continental rifting result from the interplay of local with far‐field forces. Here we study the dynamics of rifting and breakup using large‐scale numerical simulations of mantle convection with self‐consistent evolution of plate boundaries. We show that continental separation follows a characteristic evolution with four distinctive phases: (1) an initial slow rifting phase with low divergence velocities and maximum tensional stresses, (2) a synrift speed‐up phase featuring an abrupt increase of extension rate with a simultaneous drop of tensional stress, (3) the breakup phase with inception of fast sea‐floor spreading, and (4) a deceleration phase occurring in most but not all models where extensional velocities decrease. We find that the speed‐up during rifting is compensated by subduction acceleration or subduction initiation even in distant localities. Our study illustrates new links between local rift dynamics, plate motions, and subduction kinematics during times of continental separation.

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Section: Discussionmentioning

confidence: 99%

Breakup Without Borders: How Continents Speed Up and Slow Down During Rifting

Ulvrová

Brune

Williams

2019

Geophysical Research Letters

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“…SSZ zone ophiolites, such as the Vizcaíno ophiolite, are widely interpreted to form in forearc settings during the subduction initiation process (e.g., Stern et al, ; Wakabayashi et al, ), or shortly thereafter, during the first stage of overriding plate extension following subduction initiation (van Hinsbergen, Peters, et al, ). They may form both in intraoceanic settings (e.g., Philippine Sea plate; Stern & Bloomer, ) or Neotethys (Dilek & Furnes, ; Maffione et al, ; Maffione & van Hinsbergen, ; Maffione, van Hinsbergen, et al, ; Moix et al, ), as well as along or close to continental margins (e.g., the Californian Coast Range Ophiolite; Metcalf & Shervais, ; Shervais et al, ; Wakabayashi, ), the Indus‐Yarlung ophiolites of Tibet (Huang et al, ; Maffione, Thieulot, et al, ; Pozzi et al, ), or the Izmir‐Ankara ophiolites of northern Turkey (Topuz, Çelık, et al, ; Topuz, Göçmengil, et al, ).…”

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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“…A tectonic sketch explains formation and precipitation processes of the different studied vein types together with FI evolution in the proto-fore-arc setting of the N-S striking Troodos SSZ (Pearce et al, 1984;Maffione et al, 2017) exemplarily for the UPL (Fig. 8): Completely sealed syntaxial veins suffered fracturing and subsequent seawater infiltration accompanied by immediate mineral precipitation (crack and sealing process, Fig.…”

Section: Tectonic Implications-modeling Vein Precipitation In a Ssz Smentioning

confidence: 99%

Microtextures and fluid inclusions from vein minerals hosted in the Pillow Lavas of the Troodos supra-subduction zone

et al. 2018

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This study deals with microtextures and fluid inclusions from veins and vesicles hosted in the Troodos Pillow Lavas that enable a conclusive model for vein formation during the post-magmatic stage of the Troodos supra-subduction zone. Three different types of veins from the Upper and Lower Pillow Lavas are distinguished and imply different modes of fracturing, fluid flow, and precipitation. (1) Syntaxial calcite-, quartz-, and zeolite-bearing veins are interpreted as mineralized extension fractures that were pervaded by seawater. This advective fluid flow in an open system changed later into a closed system characterized by geochemical self-organization. (2) Blocky and (3) antitaxial fibrous calcite veins are associated with host rock brecciation due to hydrofracturing and diffusion-crystallization processes, respectively. Based on aqueous fluid inclusion chemistry with seawater salinities in all studied vein types, the representative fluid isochores crossed with minimum hydrostatic pressure conditions yield vein mineral precipitation temperatures between 180 and 210 °C at 250 bar, independently of the Pillow Lava units. This points to a heat source for the circulating seawater and implies that vein and vesicle minerals precipitated shortly after pillow lava crystallization under dominant isobaric cooling conditions. Compared to previous suggestions derived from secondary mineral parageneses, significant higher temperatures of vein formation in the Troodos Pillow Lavas are proposed.

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Kinematics of Late Cretaceous subduction initiation in the Neo‐Tethys Ocean reconstructed from ophiolites of Turkey, Cyprus, and Syria

Cited by 89 publications

References 163 publications

Breakup Without Borders: How Continents Speed Up and Slow Down During Rifting

Breakup Without Borders: How Continents Speed Up and Slow Down During Rifting

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

Microtextures and fluid inclusions from vein minerals hosted in the Pillow Lavas of the Troodos supra-subduction zone

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