Sharp 660-km discontinuity controlled by extremely narrow binary post-spinel transition

Ishii, Takayuki; Rong, Hong; Myhill, Robert; Fei, Hongzhan; Koemets, Iuliia; Liu, Zhaodong; Maeda, Fumihiko; Yuan, Liang; Wang, Lin; Druzhbin, Dmitry; Yamamoto, Takafumi; Bhat, Shrikant; Farla, Robert; Kawazoe, Takaaki; Tsujino, Noriyoshi; Kulik, Eleonora; Higo, Yuji; Tange, Yoshinori; Katsura, Tomoo

doi:10.1038/s41561-019-0452-1

Cited by 33 publications

(33 citation statements)

References 41 publications

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“…7a, b ). One plausible conclusion is that on average a sharper 660-km discontinuity exists beneath this region in line with mineralogical prediction 29 , 30 , compared with the 410-km discontinuity. A consistent conclusion was also obtained through fitting the waveform of P410P and P660P in NCFs 17 , which agrees with Lawrence and Shearer 31 who suggest a ~3 times thicker 410-km discontinuity relative to the 660-km discontinuity.…”

Section: Resultssupporting

confidence: 75%

Segregated oceanic crust trapped at the bottom mantle transition zone revealed from ambient noise interferometry

Feng¹,

Yao²,

Wang³

et al. 2021

Nat Commun

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The recycling of oceanic crust, with distinct isotopic and chemical signature from the pyrolite mantle, plays a critical role in the chemical evolution of the Earth with insights into mantle circulation. However, the role of the mantle transition zone during this recycling remains ambiguous. We here combine the unique resolution reflected body waves (P410P and P660P) retrieved from ambient noise interferometry with mineral physics modeling, to shed new light on transition zone physics. Our joint analysis reveals a generally sharp 660-km discontinuity and the existence of a localized accumulation of oceanic crust at the bottom mantle transition zone just ahead of the stagnant Pacific slab. The basalt accumulation is plausibly derived from the segregation of oceanic crust and depleted mantle of the adjacent stagnant slab. Our findings provide direct evidence of segregated oceanic crust trapped within the mantle transition zone and new insights into imperfect whole mantle circulation.

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Section: Resultssupporting

confidence: 75%

Segregated oceanic crust trapped at the bottom mantle transition zone revealed from ambient noise interferometry

Feng¹,

Yao²,

Wang³

et al. 2021

Nat Commun

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“…The sharp 660-km discontinuity seen in this study is consistent with an early work by Castle and Creager (2000) and a recent work by Zhang M et al (2019), which suggest that the discontinuity is at most 10 km thick, and it is marginally consistent with a previous Sto-P conversion study that concluded the discontinuity is ≤5 km thick (Yamazaki and Hirahara, 1994). A sharp 660-km discontinuity resulting from the post-spinel transition was also revealed in a recent mineral physics experiment by Ishii et al (2019). The broadened 660-km discontinuity observed before (e.g., Wang BS and Niu FL, 2010;Li J et al, 2013) was explained by the multiple phase transitions associated with dissolution of the olivine and garnet components (Wang BS and Niu FL, 2010), whereas the sharp 660-km discontinuity observed in this study referred only to the phase change of the olivine component.…”

Section: Earth and Planetary Physicssupporting

confidence: 92%

Sharpness of the paired 660-km discontinuity beneath the Izu-Bonin area

Wang

2020

Earth and Planetary Physics

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“…The water‐bearing phase in a slab located in the MTZ are expected to consist of nominally anhydrous minerals (e.g., wadsleyite and ringwoodite) and dense hydrous magnesium silicates (DHMS, such as superhydrous Phase B or Phase D) (Ohtani et al, 2004). Once ringwoodite reaches the base of the MTZ, it decomposes into LM assemblage (e.g., Ishii et al, 2018; Ishii, Huang, et al, 2019; Ishii, Kojitani, & Akaogi, 2019; Litasov et al, 2005), which is expected to host only ≈1,000 ppm of water (Fu et al, 2019; Litasov et al, 2003). Due to the release of water around 660‐km depth, this decomposition most likely causes major slab dehydration (Schmandt et al, 2014).…”

Section: Potential Impact On the Thermal Structure Of Subducting Slabsmentioning

confidence: 99%

Effect of Water on Lattice Thermal Conductivity of Ringwoodite and Its Implications for the Thermal Evolution of Descending Slabs

Marzotto

Hsieh

Ishii

et al. 2020

Geophysical Research Letters

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The presence of water in minerals generally alters their physical properties. Ringwoodite is the most abundant phase in the lowermost mantle transition zone and can host up to 1.5–2 wt% water. We studied high‐pressure lattice thermal conductivity of dry and hydrous ringwoodite by combining diamond‐anvil cell experiments with ultrafast optics. The incorporation of 1.73 wt% water substantially reduces the ringwoodite thermal conductivity by more than 40% at mantle transition zone pressures. We further parameterized the ringwoodite thermal conductivity as a function of pressure and water content to explore the large‐scale consequences of a reduced thermal conductivity on a slab's thermal evolution. Using a simple 1‐D heat diffusion model, we showed that the presence of hydrous ringwoodite in the slab significantly delays decomposition of dense hydrous magnesium silicates, enabling them to reach the lower mantle. Our results impact the potential route and balance of water cycle in the lower mantle.

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Sharp 660-km discontinuity controlled by extremely narrow binary post-spinel transition

Cited by 33 publications

References 41 publications

Segregated oceanic crust trapped at the bottom mantle transition zone revealed from ambient noise interferometry

Segregated oceanic crust trapped at the bottom mantle transition zone revealed from ambient noise interferometry

Sharpness of the paired 660-km discontinuity beneath the Izu-Bonin area

Effect of Water on Lattice Thermal Conductivity of Ringwoodite and Its Implications for the Thermal Evolution of Descending Slabs

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