Seismic discontinuities in the mantle transition zone and at the top of the lower mantle beneath eastern China and Korea: Influence of the stagnant Pacific slab

SUMMARY Constraining the distribution of water in different regions of the mantle remains one of the significant challenges to comprehend the global deep water cycle. Geomagnetic depth soundings can provide such constraint through the electrical conductivity structure. Hence, this study aims to propose a regularization technique that can estimate previously unavailable C-response. In the method, the objective function comprised an L1-norm measured data prediction error and a spectral smoothness constraint term. We used the data error of C-response to weight the predicted error. The L-BFGS method was introduced to determine the minimum point of the objective function, and the regularization parameter decreased adaptively during inversion. Thus, the geomagnetic data processed yielded high-quality C-responses in 31 stations in Eastern China. In addition, we obtained 1-D electrical conductivity profiles in the mantle transition zone (MTZ) beneath Eastern China from C-responses using the L-BFGS method. Compared with the global 1-D model, the conductivity–depth profiles revealed that the MTZ beneath Eastern China is more conductive in the east but more resistive in the west. The conversion of these conductivities to water content based on the mineral physics suggested that the MTZ beneath Eastern China is characterized by a high water concentration, approximately 0.2 and 1 wt per cent in the upper and lower MTZ, respectively. Owing to the inclusion of more stations, the water-rich region could be constrained roughly to the east of the North–South Gravity Lineament (NSGL). Further considering seismic images in the same area, this water content distribution pattern suggested that the front of the stagnant Pacific Plate in the lower MTZ might have reached the NSGL. However, the dehydration reactions in the stagnant slab were more active in the eastern part. Perhaps, some of these fluids migrated into the upper MTZ and could be the source of the trapped water found in the xenoliths from the deep upper mantle beneath Eastern China.

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Lateral Variations of the Mantle Transition Zone Structure beneath Eastern China

Bulletin of the Seismological Society of America ◽

10.1785/0120130315 ◽

2014 ◽

Vol 104 (3) ◽

pp. 1533-1539 ◽

Cited By ~ 2

Author(s):

H. Huang ◽

P. Wang ◽

N. Mi ◽

Z. Huang ◽

M. Xu ◽

...

Keyword(s):

Transition Zone ◽

Eastern China ◽

Zone Structure ◽

Mantle Transition Zone ◽

Lateral Variations

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Stability of Al-bearing superhydrous phase B at the mantle transition zone and the uppermost lower mantle

American Mineralogist ◽

10.2138/am-2018-6499 ◽

2018 ◽

Vol 103 (8) ◽

pp. 1221-1227 ◽

Cited By ~ 3

Author(s):

Sho Kakizawa ◽

Toru Inoue ◽

Hideto Nakano ◽

Minami Kuroda ◽

Naoya Sakamoto ◽

...

Keyword(s):

Transition Zone ◽

Lower Mantle ◽

Mantle Transition Zone

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Intraplate and petit-spot volcanism originating from hydrous mantle transition zone

10.5194/egusphere-egu2020-5804 ◽

2020 ◽

Author(s):

Jianfeng Yang ◽

Manuele Faccenda

Keyword(s):

Transition Zone ◽

Northeast China ◽

Subduction Zones ◽

Japan Trench ◽

Low Velocity ◽

Iranian Plateau ◽

Mantle Transition Zone ◽

Mantle Minerals ◽

Ocean Ridges ◽

Pacific Slab

<p>Most magmatism occurring on Earth is conventionally attributed to passive mantle upwelling at mid-ocean ridges, slab devolatilization at subduction zones, and mantle plumes. However, the widespread Cenozoic intraplate volcanism in northeast China and the peculiar petit-spot volcanoes offshore the Japan trench cannot be readily associated with any of these mechanisms. Furthermore, the seismic tomography images show remarkable low velocity zones (LVZs) sit above and below the mantle transition zone which are coincidently corresponding to the volcanism. Here we show that most if not all the intraplate/petit-spot volcanism and LVZs present around the Japanese subduction zone can be explained by the Cenozoic interaction of the subducting Pacific slab with a hydrous transition zone. Numerical modelling results indicate that 0.2-0.3 wt.% H<sub>2</sub>O dissolved in mantle minerals which are driven out from the transition zone in response to subduction and retreat of a stagnant plate is sufficient to reproduce the observations. This suggests that critical amounts of volatiles accumulated in the mantle transition zone due to past subduction episodes and/or delamination of volatile-rich lithosphere could generate abundant dynamics triggered by recent subduction event. This model is probably also applicable to the circum-Mediterranean and Turkish-Iranian Plateau regions characterized by intraplate/petit-spot volcanism and LVZs in the underlying mantle.</p>

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Tracing the subducting Pacific slab to the mantle transition zone with hydrogen isotopes

Scientific Reports ◽

10.1038/s41598-021-98307-y ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Takeshi Kuritani ◽

Kenji Shimizu ◽

Takayuki Ushikubo ◽

Qun-Ke Xia ◽

Jia Liu ◽

...

Keyword(s):

Transition Zone ◽

Melt Inclusions ◽

Hydrogen Isotopes ◽

Volcanic Front ◽

Mantle Transition Zone ◽

Deep Interior ◽

Terrestrial Water ◽

Quantitative Understanding ◽

Pacific Slab ◽

Slab Dehydration

AbstractHydrogen isotopes have been widely used as powerful tracers to understand the origin of terrestrial water and the water circulation between the surface and the deep interior of the Earth. However, further quantitative understanding is hindered due to a lack of observations about the changes in D/H ratios of a slab during subduction. Here, we report hydrogen isotope data of olivine-hosted melt inclusions from active volcanoes with variable depths (90‒550 km) to the subducting Pacific slab. The results show that the D/H ratio of the slab fluid at the volcanic front is lower than that of the slab fluid just behind the volcanic front. This demonstrates that fluids with different D/H ratios were released from the crust and the underlying peridotite portions of the slab around the volcanic front. The results also show that the D/H ratios of slab fluids do not change significantly with slab depths from 300 to 550 km, which demonstrates that slab dehydration did not occur significantly beyond the arc. Our estimated δD‰ value for the slab materials that accumulated in the mantle transition zone is > − 90‰, a value which is significantly higher than previous estimates.

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Garnet-controlled very low velocities in the lower mantle transition zone at sites of mantle upwelling

Terra Nova ◽

10.1111/ter.12348 ◽

2018 ◽

Vol 30 (5) ◽

pp. 333-340 ◽

Cited By ~ 2

Author(s):

Thorsten J. Nagel ◽

Erik Duesterhoeft ◽

Christian Schiffer

Keyword(s):

Transition Zone ◽

Lower Mantle ◽

Mantle Upwelling ◽

Mantle Transition Zone

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The origin of Cenozoic basalts from central Inner Mongolia, East China: The consequence of recent mantle metasomatism genetically associated with seismically observed paleo-Pacific slab in the mantle transition zone

Lithos ◽

10.1016/j.lithos.2015.11.010 ◽

2016 ◽

Vol 240-243 ◽

pp. 104-118 ◽

Cited By ~ 37

Author(s):

Pengyuan Guo ◽

Yaoling Niu ◽

Pu Sun ◽

Lei Ye ◽

Jinju Liu ◽

...

Keyword(s):

Transition Zone ◽

Inner Mongolia ◽

Mantle Metasomatism ◽

East China ◽

Mantle Transition Zone ◽

Pacific Slab

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High-pressure phase of brucite stable at Earth’s mantle transition zone and lower mantle conditions

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1611571113 ◽

2016 ◽

Vol 113 (49) ◽

pp. 13971-13976 ◽

Cited By ~ 16

Author(s):

Andreas Hermann ◽

Mainak Mookherjee

Keyword(s):

High Pressure ◽

Transition Zone ◽

Lower Mantle ◽

Direct Detection ◽

Geophysical Methods ◽

High Pressure Phase ◽

Mantle Transition Zone ◽

Earth’S Mantle ◽

3D Network ◽

Pressure Phase

We investigate the high-pressure phase diagram of the hydrous mineral brucite, Mg(OH)2, using structure search algorithms and ab initio simulations. We predict a high-pressure phase stable at pressure and temperature conditions found in cold subducting slabs in Earth’s mantle transition zone and lower mantle. This prediction implies that brucite can play a much more important role in water transport and storage in Earth’s interior than hitherto thought. The predicted high-pressure phase, stable in calculations between 20 and 35 GPa and up to 800 K, features MgO6 octahedral units arranged in the anatase–TiO2 structure. Our findings suggest that brucite will transform from a layered to a compact 3D network structure before eventual decomposition into periclase and ice. We show that the high-pressure phase has unique spectroscopic fingerprints that should allow for straightforward detection in experiments. The phase also has distinct elastic properties that might make its direct detection in the deep Earth possible with geophysical methods.

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Subducting slab morphology and mantle transition zone upwelling in double-slab subduction models with inward-dipping directions

Geophysical Journal International ◽

10.1093/gji/ggz268 ◽

2019 ◽

Vol 218 (3) ◽

pp. 2089-2105 ◽

Cited By ~ 1

Author(s):

Tianyang Lyu ◽

Zhiyuan Zhu ◽

Benjun Wu

Keyword(s):

Transition Zone ◽

Lower Mantle ◽

Numerical Models ◽

Local Maximum ◽

Substantial Effect ◽

Mantle Flow ◽

Slab Geometry ◽

Mantle Transition Zone ◽

Mantle Viscosity ◽

Deep Mantle

SUMMARY Lithospheric plates on the Earth's surface interact with each other, producing distinctive structures comprising two descending slabs. Double-slab subduction with inward-dipping directions represents an important multiplate system that is not yet well understood. This paper presents 2-D numerical models that investigate the dynamic process of double-slab subduction with inward dipping, focussing on slab geometry and mantle transition zone upwelling flow. This unique double-slab configuration limits trench motion and causes steep downward slab movement, thus forming fold piles in the lower mantle and driving upward mantle flow between the slabs. The model results show the effects of lithospheric plate properties and lower-mantle viscosity on subducting plate kinematics, overriding plate stress and upward mantle flow beneath the overriding plate. Appropriate lower-mantle strength (such as an upper–lower mantle viscosity increase with a factor of 200) allows slabs to penetrate into the lower mantle with periodical buckling. While varying the length and thickness of a long overriding plate (≥2500) does not have a substantial effect on slab geometry, its viscosity has a marked impact on slab evolution and mantle flow pattern. When the overriding plate is strong, slabs exhibit an overturned geometry and hesitate to fold. Mantle transition zone upwelling velocity depends on the speed of descending slabs. The downward velocity of slabs with a large negative buoyancy (caused by thickness or density) is very fast, inducing a significant transition zone upwelling flow. A stiff slab slowly descends into the deep mantle, causing a small upward flow in the transition zone. In addition, the temporal variation of mantle upwelling velocity shows strong correlation with the evolution of slab folding geometry. In the double subduction system with inward-dipping directions, the mantle transition zone upwelling exhibits oscillatory rise with time. During the backward-folding stage, upwelling velocity reaches its local maximum. Our results provide new insights into the deep mantle source of intraplate volcanism in a three-plate interaction system such as the Southeast Asia region.

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