Spreading process of the northern Mariana Trough: Rifting‐spreading transition at 22°N

Yamazaki, T.; Seama, Nobukazu; Okino, Kyoko; Kitada, Kazuya; Joshima, Masato; Oda, Hirokuni; Naka, Jiro

doi:10.1029/2002gc000492

Cited by 60 publications

(65 citation statements)

References 48 publications

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“…Abyssal hills have not been clearly observed in the eastern off-axis area owing to thick sedimentary coverage and/or overprinting of later arc volcanism (Fryer 1996;Martinez et al 2000). North of 14 N, the spreading center of the Mariana Trough is morphologically similar to slow-spreading mid-ocean ridges, having a deep crustal graben flanked by a zone of abyssal hills (Seama et al 2002;Yamazaki et al 2003), as expected from its slow spreading rate. However, the southern part of the Mariana Trough, where the back-arc spreading axis approaches the volcanic arc (within 10 km at around 13 20 0 N) (Martinez et al 2000), shows a broad and smooth morphological cross section and lacks a deep crustal graben (Fig.…”

Section: Geological Backgroundmentioning

confidence: 99%

“…The spreading axis lies in the eastern part of the basin, indicating asymmetric seafloor accretion (Yamazaki et al 2003;Deschamps and Fujiwara 2003;Deschamps et al 2005;Asada et al 2007). Abyssal hills have not been clearly observed in the eastern off-axis area owing to thick sedimentary coverage and/or overprinting of later arc volcanism (Fryer 1996;Martinez et al 2000).…”

Section: Geological Backgroundmentioning

confidence: 99%

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Examination of Volcanic Activity: AUV and Submersible Observations of Fine-Scale Lava Flow Distributions Along the Southern Mariana Trough Spreading Axis

Asada

Yoshikawa

Mochizuki

et al. 2014

Subseafloor Biosphere Linked to Hydrothermal Systems

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A high-resolution acoustic investigation using the AUV Urashima has revealed detailed volcanic and tectonic features along the neo-volcanic zone of the intermediate-rate spreading Southern Mariana Trough, where the high magma flux forms fast-spreading type axial high morphology. Side-scan sonar imagery suggests that the survey area mainly consists of two types of terrain: high-backscattering lumpy terrain occupies the majority of the neovolcanic zone, and low-backscattering terrain is scattered over the entire area to form various bathymetric features. Visual observations by the submersible Shinkai 6500 show that the former corresponds to bulbous pillow lava and the latter to jumbled or wrinkled sheet lavas. The estimated proportion of sheet lava with respect to study area is approximately 10 %. Pillow lavas are flatly distributed and do not form the pillow mounds that are common in the slow-spreading Mid-Atlantic Ridge. Furthermore, we did not observe any pillars, collapse features, or axial summit troughs, all of which are frequently reported in the fast-spreading East Pacific Rise.

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Section: Geological Backgroundmentioning

confidence: 99%

Section: Geological Backgroundmentioning

confidence: 99%

Examination of Volcanic Activity: AUV and Submersible Observations of Fine-Scale Lava Flow Distributions Along the Southern Mariana Trough Spreading Axis

Asada

Yoshikawa

Mochizuki

et al. 2014

Subseafloor Biosphere Linked to Hydrothermal Systems

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“…The studies of the geomagnetic anomalies using the Matuyama-Brunhes boundary (0.78 Ma) reported the similarity in the spreading trend; the full spreading rates are 10 km/Myr at 22 N in the northern end (Yamazaki et al 2003) and~64 km/Myr in maximum at 13 N in the southern end (Martinez et al 2000). These two different methods show that the full spreading rate of the Southern Mariana Trough back-arc basin ranges 45-64 km/Myr.…”

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confidence: 99%

Asymmetric Seafloor Spreading of the Southern Mariana Trough Back-Arc Basin

Seama

Okino

2014

Subseafloor Biosphere Linked to Hydrothermal Systems

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We compiled multi-narrow beam bathymetric data and geomagnetic field data obtained by a series of JAMSTEC research cruises in the Southern Mariana Trough back-arc basin, where is selected as one of three integrated target sites for the Japanese TAIGA Project. The bathymetric data are used to trace the non-transform offsets that define the ridge segments at the offaxis, and to characterize the seafloor morphology signatures from the bathymetry profiles across the spreading axes of two ridge segments. The geomagnetic field data are used to derive the crustal magnetization distribution and to estimate the spreading rate of the southern segment. Both of the spreading rate and the seafloor deepening rate of the southern segment support highly asymmetric seafloor spreading; much faster spreading in the west side of the spreading axis compared to the east side (trench side). We estimated the full spreading rate as 46 km/Myr with its half rate of 33 km/Myr for the west side and 13 km/Myr for the east side. In contrast to the southern segment, our results indicate that the northern segment has a different style of the asymmetric seafloor spreading; that is accompanied by an obvious trace of a ridge jump to the trench side. The local symmetry axis in the bathymetry profiles locates at a distance of 18 km to the west from the spreading axis, suggesting that it is the failed spreading axis due to the ridge jump. The location of this failed spreading axis coincides with the center of the bull's eye feature in the Mantle Bouguer anomaly, suggesting that the ridge jump to the trench side with an increase in the magma supply. We propose that the influence of the low viscosity region in the mantle wedge due to hydration driven by water release from the subducting slab leads to the highly asymmetric seafloor spreading; the low viscosity mantle would preferentially captures the mantle upwelling zone beneath the spreading axis as the spreading axis has been kept in the area closed to the low viscosity region in the mantle wedge, resulting in the highly asymmetric seafloor spreading. Further, the different styles of the asymmetric seafloor spreading between the northern segment and the southern segment probably show evidence that the influence varies with the distance from the low viscosity region in the mantle wedge.

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“…The spreading rates of the Mariana Trough back-arc basin increase from the north to the south. Studies of the geomagnetic anomalies using the Matuyama-Brunhes boundary (0.78 Ma) reported the full spreading rates of 10 km/Myr at 22 N in the northern end (Yamazaki et al 2003) and of~64 km/Myr in maximum at 13 N in the southern end (Martinez et al 2000). Repeated GPS surveys in the Mariana Islands show similar trend of the full spreading rates; that is 15.9 AE 6.6 km/Myr at 18.7 N and 44.6 AE 2.7 km/Myr at 13.6 N (Kato et al 2003).…”

Section: Introductionmentioning

confidence: 99%

The Mantle Dynamics, the Crustal Formation, and the Hydrothermal Activity of the Southern Mariana Trough Back-Arc Basin

Seama

Sato

Nogi

et al. 2014

Subseafloor Biosphere Linked to Hydrothermal Systems

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The Southern Mariana Trough back-arc basin is a currently active back arc basin, and it has fast spreading morphologic and geophysical characteristics, suggesting an additional magma supply, even though the full spreading rate is categorized as slow spreading. Five hydrothermal vent sites have been found within 5 km around the spreading axis at 13 N. The Japanese TAIGA Project selected this area as one of three integrated target sites, and TAIGA Project members conducted series of JAMSTEC research cruises for different types of geophysical surveys, together with dive observation and samplings by the submersible Shinkai 6500. We reviewed the results from these geophysical surveys and the volcanic rock samples to summarize the products from the TAIGA Project. The results provide strong constraints on the mantle dynamics and the crustal formation at the Southern Mariana Trough back-arc basin; all the results support that they are influenced by hydration derived from the subducting slab with accompanying the additional magma supply. Furthermore, the results from the geophysical and geological surveys for the five hydrothermal vent sites provide characteristic features on the hydrothermal activity and the features are different between on-axis and off-axis hydrothermal sites. The on-axis hydrothermal site is associated with an episodic diking event followed by fissures in a fourth order ridge segment, and its duration and size vary depending on the episodic diking event and on the fissures following. In contrast, the formation of the off-axis hydrothermal sites is closely related to the residual heat from the volcanism rather than tectonic stresses accompanied by faults, and the off-axis hydrothermal activity is for a long period and in a large scale. We summarized all the evidence to propose our scenario of the mantle dynamics, the crustal formation, and the hydrothermal activity of the Southern Mariana Trough back-arc basin.

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Spreading process of the northern Mariana Trough: Rifting‐spreading transition at 22°N

Cited by 60 publications

References 48 publications

Examination of Volcanic Activity: AUV and Submersible Observations of Fine-Scale Lava Flow Distributions Along the Southern Mariana Trough Spreading Axis

Examination of Volcanic Activity: AUV and Submersible Observations of Fine-Scale Lava Flow Distributions Along the Southern Mariana Trough Spreading Axis

Asymmetric Seafloor Spreading of the Southern Mariana Trough Back-Arc Basin

The Mantle Dynamics, the Crustal Formation, and the Hydrothermal Activity of the Southern Mariana Trough Back-Arc Basin

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