The First 10 Million Years of Rear‐Arc Magmas Following Backarc Basin Formation Behind the Izu Arc

Miyazaki, Takashi; Gill, James B.; Hamelin, C.; DeBari, S. M.; Sato, Tadasu; Tamura, Yoshihiko; Kimura, Jun–Ichi; Vaglarov, Bogdan Stefanov; Chang, Qing; Senda, Ryoko; Haraguchi, Satoru

doi:10.1029/2020gc009114

Cited by 5 publications

(3 citation statements)

References 67 publications

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“…Those features reflect a distinctive combination of the extent of prior mantle depletion, the depth and degree of mantle melting, and the nature and amount of the slab component. In Izu, the S‐shaped REE pattern in particular has been shown to indicate 2%–4% melting at ∼1.5 GPa of mantle more depleted than DMM to which ∼0.5% of hydrous melt was added from a slab 120–140 km deep (Miyazaki et al., 2020). We infer variations on this theme along and across the strike of the HT and suggest that the S‐shaped REE patterns may characterize the rifting stage of backarc development in general because they seem to be absent from the spreading stage of the Lau Basin and Mariana Trough.…”

Section: Discussionmentioning

confidence: 99%

“…They predate the current phase of rifting in Izu and cannot be traced across its ∼100‐km wide extensional zone to connect to arc front volcanoes. They did not develop until several million years after “rift‐type” volcanism (Miyazaki et al., 2020; Sato et al., 2020). Therefore, the messy spatial distribution of slab components in the HT may have a temporal dimension as well, and be commonplace during rifting and prior to spreading.…”

Section: Discussionmentioning

confidence: 99%

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Basalt Geochemistry and Mantle Flow During Early Backarc Basin Evolution: Havre Trough and Kermadec Arc, Southwest Pacific

Gill

Hoernle

Todd

et al. 2021

Geochem Geophys Geosyst

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The Havre Trough (HT) backarc basin in the southwest Pacific is in the rifting stage of development. We distinguish five types of basalt there based on their amount and kind of slab component: backarc basalts (BAB) with little or no slab component, modified BAB with slight amounts, reararc (RA) with more, remnants of the preexisting arc (Colville Ridge horsts), and arc front volcanoes within the HT. Previous subarc mantle is quickly removed and replaced by more fertile mantle with less slab component. The ambient mantle is “Pacific” isotopically, and more enriched in Nb/Yb and Nd and Hf isotope ratios north of the Central Kermadec Discontinuity at 32°S than to the south. The contrast may reflect inheritance in the south of mantle that was depleted during spreading that formed the southern South Fiji Basin and a higher degree of melting because of a wetter slab‐derived flux. The slab component also differs along strike, more like a dry melt in the north and a supercritical fluid in the south. The mass fraction of slab component increases southward in the backarc as well as the arc front. RA volcanoes have the most slab component (1%–2%) and form indistinct ridges at high angles to, and <50 km behind, frontal volcanoes. Backarc basalts have less and occur throughout the basin. Slab components are distributed further into the backarc, and more irregularly, during the rifting than spreading stage of backarc basin development. The rifting stage is disorganized geochemically as well as spatially.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Basalt Geochemistry and Mantle Flow During Early Backarc Basin Evolution: Havre Trough and Kermadec Arc, Southwest Pacific

Gill

Hoernle

Todd

et al. 2021

Geochem Geophys Geosyst

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“…But formation of back-arc basins in front of advancing hinges at Izu-Bonin (Miyazaki et al, 2020) and Mariana (Wu et al, 2016) subductions raises concerns about the universality of such a mechanism. Furthermore, the fact that in some cases (Japan Sea Basin, South Fiji Sea Basin) back arc extension came to an end while subduction continued indicates that subduction is not a sufficient condition for back-arc opening.…”

Section: Introductionmentioning

confidence: 99%

Formation of back-arc basins by lithospheric warping: examples of the Andaman, Bismarck and Banda Sea basins

Orvos¹

2023

Preprint

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Back-arc basins represent an intriguing phenomenon of the lithospheric evolution. They are the places of potential subduction initiation, what makes them highly important features within the theory of plate tectonics. The circumstances of their origin and life cycle are not well understood and whether the retreat of subduction is a cause or consequence of back-arc basin development remains an open issue. In the presented work, a new approach has been used, based on the model of thin shell warping. Within this concept, the plate warps due to proximity of translational boundary when its forward movement is constrained. Following the process, the lithospheric slab can steepen, roll-back and sink to the 660 km transition layer, reaching an amphitheatre-like geometry. The specific shape of deformation resembles the topology of several reference basins. Results show that subduction retreat, back-arc extension and arcuate geometry may only represent different demonstrations of one underlying physical mechanism. Modelling suggests that the movement of plates and their interactions, together with the curvature of the Earth’s surface, could be responsible for the formation of back-arc basins.

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Geochemical constraints on the geodynamic setting of Alborz-Azerbaijan Cenozoic magmatism

Honarmand,

van der Boon,

Neubauer

et al. 2024

Chemical Geology

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The First 10 Million Years of Rear‐Arc Magmas Following Backarc Basin Formation Behind the Izu Arc

Cited by 5 publications

References 67 publications

Basalt Geochemistry and Mantle Flow During Early Backarc Basin Evolution: Havre Trough and Kermadec Arc, Southwest Pacific

Basalt Geochemistry and Mantle Flow During Early Backarc Basin Evolution: Havre Trough and Kermadec Arc, Southwest Pacific

Formation of back-arc basins by lithospheric warping: examples of the Andaman, Bismarck and Banda Sea basins

Geochemical constraints on the geodynamic setting of Alborz-Azerbaijan Cenozoic magmatism

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