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Tidal tomography constrains Earth’s deep-mantle buoyancy

Harriet C. P. Lau (), Jerry X. Mitrovica, James L. Davis, Jeroen Tromp, Hsin-Ying Yang and David Al-Attar
Additional contact information
Harriet C. P. Lau: Harvard University
Jerry X. Mitrovica: Harvard University
James L. Davis: Lamont-Doherty Earth Observatory, Columbia University
Jeroen Tromp: Princeton University
Hsin-Ying Yang: Laboratory of Seismology and Physics of Earth’s Interior & School of Earth and Space Sciences, University of Science and Technology of China
David Al-Attar: University of Cambridge

Nature, 2017, vol. 551, issue 7680, 321-326

Abstract: Abstract Earth’s body tide—also known as the solid Earth tide, the displacement of the solid Earth’s surface caused by gravitational forces from the Moon and the Sun—is sensitive to the density of the two Large Low Shear Velocity Provinces (LLSVPs) beneath Africa and the Pacific. These massive regions extend approximately 1,000 kilometres upward from the base of the mantle and their buoyancy remains actively debated within the geophysical community. Here we use tidal tomography to constrain Earth’s deep-mantle buoyancy derived from Global Positioning System (GPS)-based measurements of semi-diurnal body tide deformation. Using a probabilistic approach, we show that across the bottom two-thirds of the two LLSVPs the mean density is about 0.5 per cent higher than the average mantle density across this depth range (that is, its mean buoyancy is minus 0.5 per cent), although this anomaly may be concentrated towards the very base of the mantle. We conclude that the buoyancy of these structures is dominated by the enrichment of high-density chemical components, probably related to subducted oceanic plates or primordial material associated with Earth’s formation. Because the dynamics of the mantle is driven by density variations, our result has important dynamical implications for the stability of the LLSVPs and the long-term evolution of the Earth system.

Date: 2017
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DOI: 10.1038/nature24452

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