Sound velocities of aluminum‐bearing stishovite in the mantle transition zone

Gréaux, Steeve; Kono, Yoshio; Wang, Yanbin; Yamada, Akihiro; Zhou, Chunyin; Jing, Zhi-Cheng; Inoue, Toru; Higo, Yuji; Irifune, Tetsuo; Sakamoto, Naoya; Yurimoto, H.

doi:10.1002/2016gl068377

Cited by 17 publications

(6 citation statements)

References 64 publications

(157 reference statements)

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“…However, the presence of liebermannite alone cannot account for the positive velocity anomaly observed in the upper mantle beneath the Philippine Sea (Tarits & Mandéa, 2010) and northeastern China (Kelbert et al, 2009) because the elastic wave velocities measured in liebermannite are comparable with those of common mantle mineral phases (Caracas & Boffa Ballaran, 2010; Mookherjee & Steinle‐Neumann, 2009). Instead, the seismic wave velocities of Al‐poor stishovite, another principal mineral phase stable in subducting continental sediments, are notably faster than those of mantle mineral phases (Gréaux et al, 2016). The stishovite coexisting with liebermannite in our samples is noticeably devoid of aluminum (Table 2).…”

Section: Discussionmentioning

confidence: 99%

The Electrical Conductivity of Liebermannite: Implications for Water Transport Into the Earth's Lower Mantle

et al. 2020

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Liebermannite (KAlSi3O8) is a principal mineral phase expected to be thermodynamically stable in deeply subducted continental and oceanic crusts. The crystal structure of liebermannite exhibits tunnels that are formed between the assemblies of double chains of edge‐sharing (Si, Al) O6 octahedral units, which act as a repository for large incompatible alkali ions. In this study, we investigate the electrical conductivity of liebermannite at 12, 15, and 24 GPa and temperature of 1500 K to track subduction pathways of continental sediments into the Earth's lower mantle. Further, we looked at whether liebermannite could sequester incompatible H2O at deep mantle conditions. We observe that the superionic conductivity of liebermannite due to the thermally activated hopping of K+ ions results in high electrical conductivity of more than 1 S/m. Infrared spectral features of hydrous liebermannite indicate the presence of both molecular H2O and hydroxyl (OH−) groups in its crystal structure. The observed high electrical conductivity in the mantle transition zone beneath Northeastern China and the lower mantle beneath the Philippine Sea can be attributed to the subduction pathways of continental sediments deep into the Earth's mantle. While major mineral phases in pyrolitic compositions are almost devoid of H2O under lower mantle conditions, our study demonstrates that liebermannite could be an important host of H2O in these conditions. We propose that the relatively high H2O contents of ocean island basalts derived from deep mantle plumes are primarily related to deeply subducted continental sediments, in which liebermannite is the principal H2O carrier.

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Section: Discussionmentioning

confidence: 99%

The Electrical Conductivity of Liebermannite: Implications for Water Transport Into the Earth's Lower Mantle

et al. 2020

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“…ν jumps across the transition. Elasticity data for different compositions in the literature are also plotted for comparison (Gréaux et al., 2016; Lakshtanov et al., 2007a; Zhang et al., 2021).…”

Section: Discussionmentioning

confidence: 99%

“…On the other hand, thermoelastic parameters for CaPv are obtained by refitting combined elasticity data sets from Gréaux et al (2019) and Sun et al (2016) (Table S10 in Supporting Information S1). We should note that the CaPv data by Thomson et al (2019) are not used here because they measured sound velocities at a nearly constant pressure such that some thermoelastic parameters cannot be reliably constrained such as pressure derivatives of K S and μ. Mie-Grüneisen EOS and finite-strain theory are then used to calculate ρ, K S , and μ of each mineral phase in the MORB mineralogy along a cold subducting slab based on the following equations (Stixrude & Lithgow-Bertelloni, 2005): (Gréaux et al, 2016;Lakshtanov et al, 2007a;Zhang et al, 2021). We should note that the finite-strain model cannot be applied to evaluate the shear softening feature across the post-stishovite ferroelastic transition at high P-T conditions.…”

Section: Velocity Profiles Of Subducted Morb Across the Post-stishovi...mentioning

confidence: 99%

“…The Al 3+ and/or H + incorporation in stishovite can reduce the post‐stishovite transition pressure to the depth range more consistent with the seismic observations of the regional V S anomalies in the shallow lower mantle (Lakshtanov et al., 2007b; Umemoto et al., 2016). Although full elasticity of pure stishovite and post‐stishovite and the effect of Al on the post‐stishovite transition pressure have been relatively well investigated (Asahara et al., 2013; Karki et al., 1997; Lakshtanov et al., 2007b; Li et al., 1996; Shieh et al., 2002; Yang & Wu, 2014; Zhang et al., 2021), elasticity data of hydrated Al‐bearing stishovite across the post‐stishovite transition remain largely unexplored (Bolfan‐Casanova et al., 2009; Gréaux et al., 2016; Lakshtanov et al., 2007a). This is mainly due to the technical difficulty in measuring sound velocities and reliably deriving full elastic moduli ( C ij ) of the stishovite crystal at high pressure (Zhang et al., 2021).…”

Section: Introductionmentioning

confidence: 99%

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Elasticity of Hydrated Al‐Bearing Stishovite and Post‐Stishovite: Implications for Understanding Regional Seismic V_S Anomalies Along Subducting Slabs in the Lower Mantle

Zhang

Karato³

et al. 2022

JGR Solid Earth

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Seismic tomographic studies have revealed wide-spread stagnant slabs in the mantle beneath subduction zones (Fukao & Obayashi, 2013). The subducting slabs contain Mid-Ocean Ridge Basalt (MORB) and other crustal and sedimentary materials that are chemically and physically distinct from the lithospheric mantle (Ringwood, 1975). As slab subduction occurs deeper into the lower mantle, basaltic materials are expected to exhibit distinct mineralogy and physical properties that may be revealed seismically (Ishii et al., 2019;Rost et al., 2008). Compared with the mantle lithosphere of approximately 100-200 km thick, the oceanic crust is only ∼7 km thick

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“…data are plotted for ringwoodite 13,58,64 , wadsleyite 50,60 , majorite 55 , ferropericlase 53,65 , bridgmanite 5 , NALphase 151 . Polycrystalline data are for wadsleyite 152 , majoritic garnet 153 , ferropericlase (magnesiowüstite) 6,32 , bridgmanite 6 , stishovite 81,154 , CaPv 7,11,82 , post-perovskite 77 (measured up to 172 GPa). The scribbled regions shows the approximate range of PT-conditions that have been reached using the respective high-PT apparatus, but where few or no elasticity measurements have been performed to-date.…”

Section: Box 2 Anisotropy and Averaging Schemesmentioning

confidence: 99%

Experimental elasticity of Earth’s deep mantle

Marquardt

Thomson

2020

Nat Rev Earth Environ

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Remote sensing by seismology provides increasingly detailed views on the seismic wave velocity structure of Earth's deep mantle. The interpretation of these observations critically relies on quantitative knowledge of the elastic properties of Earth's mantle minerals. This knowledge comes largely from experimental in-situ measurements of sound wave velocities of mantle minerals at high-pressure/-temperature, a field that has significantly evolved within the past decade. In this Technical Review, we highlight the major methodologies employed and discuss their advantages, limitations and future potential. We focus on light scattering techniques in the diamond-anvil cell and ultrasonic methods in large volume presses since these techniques have provided -and likely will provide -the majority of elasticity data on deep mantle minerals in the foreseeable future. We summarize the current state of knowledge with respect to the elastic properties of the minerals making up the transition zone and lower mantle, where substantial advances have been recently made, and highlight major gaps in published data.

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Sound velocities of aluminum‐bearing stishovite in the mantle transition zone

Cited by 17 publications

References 64 publications

The Electrical Conductivity of Liebermannite: Implications for Water Transport Into the Earth's Lower Mantle

The Electrical Conductivity of Liebermannite: Implications for Water Transport Into the Earth's Lower Mantle

Elasticity of Hydrated Al‐Bearing Stishovite and Post‐Stishovite: Implications for Understanding Regional Seismic V_S Anomalies Along Subducting Slabs in the Lower Mantle

Experimental elasticity of Earth’s deep mantle

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Sound velocities of aluminum‐bearing stishovite in the mantle transition zone

Cited by 17 publications

References 64 publications

The Electrical Conductivity of Liebermannite: Implications for Water Transport Into the Earth's Lower Mantle

The Electrical Conductivity of Liebermannite: Implications for Water Transport Into the Earth's Lower Mantle

Elasticity of Hydrated Al‐Bearing Stishovite and Post‐Stishovite: Implications for Understanding Regional Seismic VS Anomalies Along Subducting Slabs in the Lower Mantle

Experimental elasticity of Earth’s deep mantle

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Elasticity of Hydrated Al‐Bearing Stishovite and Post‐Stishovite: Implications for Understanding Regional Seismic V_S Anomalies Along Subducting Slabs in the Lower Mantle