Kinetics and pulses of zircon growth in migmatites beneath a volcanic arc: An example from the high‐<i>T</i> Ryoke Complex, southwest Japan

Miyazaki, Kazuhiro; Ikeda, Takeshi; Iwano, Hideki; Hirata, Takafumi; Danhara, Tohru

doi:10.1111/jmg.12711

Cited by 6 publications

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References 68 publications

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“…2: Higo metamorphism (Sakashima et al 2003;Maki et al 2014;Tsutsumi 2020;Kawaguchi et al 2020). 3-6: Ryoke metamorphism (Skrzypek et al 2018;Takatsuka et al 2018;Kawakami et al 2019Kawakami et al , 2022Miyazaki et al 2022) million years younger than 60 Ma is reported not only from the Daito granodiorite but also the Korean Peninsula and detrital zircon chronology (e.g., Tokiwa et al 2016;Cheong and Jo 2017;Nakano et al 2021), it is possible that more data on igneous ages in SW Japan will show the start of this magmatic hiatus is somewhat younger.…”

Section: Magmatic Hiatus: Ridge Subduction At 60-46 Mamentioning

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Clockwise rotation of SW Japan and timing of Izanagi–Pacific ridge subduction revealed by arc migration

Yamaoka,

Wallis

2023

Prog Earth Planet Sci

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Igneous rocks associated with the Cretaceous to Paleogene volcanic arc in SW Japan show ages that young from west to east in a direction parallel to the Median Tectonic Line suggesting corresponding translation of a heat source traditionally interpreted in terms of oblique subduction of a spreading ridge. However, recent oceanic plate reconstructions suggest ridge subduction may be younger than the main arc activity. Age compilations of 1227 points of felsic to intermediate Cretaceous and Cenozoic igneous rocks from the Japan arc show arc magmatism that can be separated into an early active period 130–60 Ma (stage 1), a subsequent period of quiescence 60–46 Ma (stage 2), which is followed by a resumption of igneous activity from 46 Ma onward (stage 3). In southwest Japan, the orientations of the magmatic arcs of stages 1 and 3 show and angular discordance of about 20°. The lack of active arc magmatism and the occurrence patterns of adakitic and high-Mg andesitic magmas indicate that ridge subduction occurred during stage 2. The arc age distribution pattern of stage 1 is explained by the slab shallowing related to a younging of the subducting slab as the ridge approaches. Furthermore, the obliquity of the arcs formed at stages 1 and 3 is explained by a 20° clockwise rotation of the inner zone of southwest Japan during the ridge-subduction phase. Oceanic plate reconstructions show counterclockwise rotation in the subduction direction after the ridge subduction phase, and coupling of the subducting oceanic plate with the upper plate would support microplate rotation in the inner zone. The new proposed tectonic reconstructions provide a framework to related Paleogene subduction of an active spreading ridge along the east Asia margin not only to the distribution of granitic bodies but also to rift-related basin formation on the eastern margin of the Eurasian continent and to rotation of crustal blocks indicated by paleomagnetic data of Cretaceous terranes.

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