Water delivered to the mantle by aluminum enriched hydrated slabs?

Velocities of aluminum enriched superhydrous phase B suggest the presence of hydrated mantle regions beneath subduction zones

【Fig.1_Effect of Al + H incorporation on the sound velocities of superhydrous phase B】
Schematic representation of the incorporation of aluminum together with water (as Al + H) in the crystal structure of superhydrous phase B.

【Fig.2_Velocities of superhydrous phase B as a function of Al + H content】
Longitudinal (VP) and shear (VS) velocities of superhydrous phase B as function of Al + H content. Full symbols represent the aluminum-free SuB (Xu et al., 2022; Li et al., 2016; Rosa et al., 2015) while the open symbols are the aluminum bearing SuB of this study and Li et al. (2022).

Dense Hydrous Magnesium Silicates (DHMSs) are generally considered as primary water carriers from the shallow lithosphere to the deep mantle transition region (MTR; 410–660 km in depth). Among DHMSs, Superhydrous phase B (hereafter, SuB) holds the chemical formula, Mg10Si3H3O18. This phase is believed to hold a large amount of water and thus may have an important role in the water storage capacity of the MTR and the transportation of water to the deeper parts of the Earth’s interior; but because of its relative instability against the high temperature of the Earth’s mantle, SuB is generally associated with cold regions, such as the inner parts of the subducted slab. A recent experimental study conducted at Ehime University, however, showed that when aluminum incorporates SuB, its stability against temperature is drastically improved (Kakizawa et al., AmMin 2018), allowing this mineral to remain stable at pressure and temperature conditions matching those of the Earth’s lower mantle.

In 2022, the same  Ehime University research team reported the longitudinal (VP) and shear (VS) velocities of SuB (Xu et al., GRL 2022) using the X-ray and ultrasonic techniques implemented in a multi-anvil apparatus at the beamline BL04B1, located at the synchrotron facility, SPring-8, in Japan. The results showed that the presence of SuB could be correlated with the low seismic velocities observed in subducted slab regions. This time, they carried out similar high pressure and high temperature measurements on SuB samples doped with aluminum (Fig.1). Their new data suggest that incorporation of aluminum in SuB (Al-bearing SuB in Fig.2) promotes unusual variations of velocities with an increase in water content compared to the velocities of SuB without aluminum (Al-free SuB in Fig.2).

This new finding, in addition to the knowledge that the stability against temperature and capacity to store water of SuB are improved when aluminum is present in its structure, suggests that the Al-bearing SuB may account for seismically visible anomalies at the bottom of the MTR and beneath subduction zones in the uppermost lower mantle. These results should greatly contribute to tracing the existence and recycling of the former hydrated lithospheric crust in the Earth’s lower mantle and interpreting seismic velocities in terms of mantle composition, and estimate the amount of water that could be passed down to the deep mantle.

Published: 07 Aug 2024

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Funding information:

Japan Society for the Promotion of Science (JSPS) Doctor course Fellowship,
Japan Society for the Promotion of Science (JSPS) Grant-in-Aid for JSPS Fellows, Grant Number 18J12511,
National Natural Science Foundation of China (42003050, 42073063, 41902035)