Evolution processes of <scp>O</scp>rdovician–<scp>D</scp>evonian arc system in the <scp>S</scp>outh‐<scp>K</scp>itakami <scp>M</scp>assif and its relevance to the <scp>O</scp>rdovician ophiolite pulse

Ozawa, Kazuhito; Maekawa, Hirokazu; Shibata, Ken; Asahara, Yoshihiro; Yoshikawa, Masakazu

doi:10.1111/iar.12100

Cited by 16 publications

(7 citation statements)

References 163 publications

(488 reference statements)

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“…Modern discrimination schemes by Vermeesch (2006aVermeesch ( , 2006b) also suggest a N-MORB and IAB geochemical characteristic (Figures 4e and 4f). The presence of plagioclase-bearing peridotites suggest a back-arc setting (e.g., Kimura et al, 2020;Ozawa et al, 2015). In general, the plagioclase peridotites are uncommon among the global abyssal peridotite suites, and have been reported from slow-spreading ridges (e.g., Dick, 1989;Warren, 2016).…”

Section: Eruption Time and Tectonic Settingmentioning

confidence: 99%

Cretaceous to Miocene NW Pacific Plate Kinematic Constraints: Paleomagnetism and Ar–Ar Geochronology in the Mineoka Ophiolite Mélange (Japan)

et al. 2021

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East Asia has witnessed the birth and demise of oceanic plates at least, during the latest 500 million years. Subduction of numerous oceanic plates: Eurasian (Amur), Pacific, North America (Okhotsk), Indo-Australia, Caroline, and Philippine Sea plates formed a complex collage of ophiolites, volcanic arcs, orogenic belts, and continental fragments (i.e., terranes, blocks, and massifs) over East Asia (e.g.

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Section: Eruption Time and Tectonic Settingmentioning

confidence: 99%

Cretaceous to Miocene NW Pacific Plate Kinematic Constraints: Paleomagnetism and Ar–Ar Geochronology in the Mineoka Ophiolite Mélange (Japan)

et al. 2021

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“…53 and 45 Ma, a wave of dynamic/ RESEARCH thermal uplift (Smith et al, 2014) and magmatism (Tepper, 2016) migrated southwestward (trenchward) across the northwestern United States. This activity is attributed to rollback of the Farallon slab following the accretion of Siletzia, and in other arcs, rollback has been identified as a precursor to slab breakoff (Lucente and Margheriti, 2008;Ozawa et al, 2015).…”

Section: Tectonic Settingmentioning

confidence: 99%

Eocene Basalt of Summit Creek: Slab breakoff magmatism in the central Washington Cascades, USA

et al. 2018

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The early Eocene (52-44 Ma) was a time of tectonic reorganization and widespread magmatism in Washington, Oregon, and British Columbia (west coast of the United States and Canada) that culminated with establishment of the Cascade arc. Details of this tectonic transition remain enigmatic, and diverse scenarios involving ridge-trench interaction, slab breakoff, and/or plume magmatism have been proposed. This study focuses on the ca. 48 Ma Basalt of Summit Creek, a ~1500-m-thick sequence of subaerial lavas that erupted during the interval of time between accretion of the Siletzia terrane to the west and inception of the Cascade arc. The sequence dominantly consists of moderately evolved tholeiitic basalts (9.3-3.1 wt% MgO; Mg# = 0.66-0.29) and scarce rhyolites that erupted in the forearc but are chemically and isotopically similar to oceanic basalts of the Crescent Formation, found ~100 km to the west as part of the Siletzia terrane. Basalt of Summit Creek lavas lack subduction signatures (e.g., high field strength element depletions) and require a mechanism whereby asthenospheric melts were able to reach the surface having undergone little or no chemical interaction with fluids derived from the subducting slab or metasomatized mantle. We suggest that the accretion of Siletzia led to breakoff of the Farallon slab, and that Basalt of Summit Creek lavas formed by decompression melting of mantle that upwelled through the rupture. Slab breakoff typically produces a short-lived linear magmatic belt; the Basalt of Summit Creek appears to be part of such a belt, previously unrecognized, that parallels the Siletzia boundary and formed between 50 and 48 Ma.

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“…The Kitakami Belt, northeast Japan, comprises a series of Early Paleozoic to Jurassic geological terranes (Figure 1). Particularly, the South Kitakami Belt contains Early Paleozoic complexes, the Hayachine-Miyamori Ophiolite (Kimura et al, 2020;Ozawa, 1988;Ozawa et al, 2015;Ozawa & Shimizu, 1995) and the Motai metamorphic rocks, (serpentinite with metamorphic rocks; Maekawa, 1981) and is considered to be one of the oldest geological terranes in Japan, as well as the Oeyama Ophiolite and Kurosegawa Belt in southwest Japan (cf. Ehiro et al, 2016;Ishiwatari et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Ehiro et al, 2016;Ishiwatari et al, 2016). Ozawa et al (2015) interpreted the Hayachine-Miyamori Ophiolite as fragments of an Early Paleozoic arc-backarc system and also regarded the Motai metamorphic rocks as subducted oceanic materials in the forearc regions of the Hayachine-Miyamori subduction zone.…”

Section: Introductionmentioning

confidence: 99%

“…According to the model of Ozawa et al (2015), the South Kitakami Belt preserves the fragments of a cross-section from forearc to backarc in a subduction zone and therefore plays an essential role in understanding the evolution of a subduction system on an Early Paleozoic East Asian continental margin. Although the field occurrence and petrographic description of the Motai serpentinites were given by Shimazu (1954aShimazu ( , 1954b, Maekawa (1981), and Machida and Ishiwatari (2013), detailed petrological characteristics of the Motai serpentinites are lacking from the viewpoint of forearc mantle wedge materials.…”

Section: Introductionmentioning

confidence: 99%

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Slab‐fluid metasomatism in the Early Paleozoic forearc mantle deduced from the Motai serpentinites, South Kitakami Belt, northeast Japan

et al. 2021

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The present study examines the petrology and geochemistry of the Early Paleozoic Motai serpentinites, the South Kitakami Belt, northeast Japan, to reveal the subduction processes and tectonics in the convergent margin of the Early Paleozoic proto-East Asian continent. Protoliths of the serpentinites are estimated to be harzburgite to dunite based on the observed amounts of bastite (orthopyroxene pseudomorph). Relic chromian spinelCr# [=Cr/(Cr + Al)] increases with decreasing amount of bastite. The compositional range of chromian spinel is similar to that found in the Mariana forearc serpentinites. This fact suggests that the protoliths of the serpentinites are depleted mantle peridotites developed beneath the forearc regions of a subduction zone. The Motai serpentinites are divided into two types, namely, Types 1 and 2 serpentinites; the former are characterized by fine-grained antigorite and lack of olivine, and the latter have coarse-grained antigorite and inclusion-rich olivine. Caamphibole occurs as isolated crystals or vein-like aggregates in the Type 1 serpentinites and as needle-shaped minerals in the Type 2 serpentinites. Caamphibole of the Type 1 serpentinites is more enriched in LILEs and LREEs, suggesting the influence of hydrous fluids derived from slabs. By contrast, the mineral assemblage, mineral chemistry, and field distribution of the Type 2 serpentinites reflect the thermal effect of contact metamorphism by Cretaceous granite. The Caamphibole of the Type 1 serpentinites is different from that of the Hayachine-Miyamori Ophiolite in terms of origin; the latter was formed by the infiltration of melts produced in an Early Paleozoic arc-backarc system. Chemical characteristics of the Ca-amphibole in the ultramafic rocks in the South Kitakami Belt reflect the tectonics of an Early Paleozoic mantle wedge, and the formation of the Motai metamorphic rocks in the forearc region of the Hayachine-Miyamori subduction zone system, which occurred at the Early Paleozoic proto-East Asian continental margin.

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Evolution processes of Ordovician–Devonian arc system in the South‐Kitakami Massif and its relevance to the Ordovician ophiolite pulse

Cited by 16 publications

References 163 publications

Cretaceous to Miocene NW Pacific Plate Kinematic Constraints: Paleomagnetism and Ar–Ar Geochronology in the Mineoka Ophiolite Mélange (Japan)

Cretaceous to Miocene NW Pacific Plate Kinematic Constraints: Paleomagnetism and Ar–Ar Geochronology in the Mineoka Ophiolite Mélange (Japan)

Eocene Basalt of Summit Creek: Slab breakoff magmatism in the central Washington Cascades, USA

Slab‐fluid metasomatism in the Early Paleozoic forearc mantle deduced from the Motai serpentinites, South Kitakami Belt, northeast Japan

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