AVO 4 orthovanadates are materials of fundamental and technological importance due to
the large variety of functional properties exhibited by them. These materials have potential …

The terrestrial planets accreted from a diverse suite of solar system materials ranging from
strongly O-deficient materials similar to enstatite chondrites via ordinary chondrite materials …

Laboratory measurements of sound velocities of high-pressure minerals provide crucial
information on the composition and constitution of the deep mantle via comparisons with …

Accurate knowledge of the mineralogy is essential for understanding the lower mantle,
which represents more than half of Earth's volume. CaSiO3 perovskite is believed to be the …

A substantial amount of subducted basaltic crusts may exist in the lower mantle. It features
distinct chemical composition from the peridotitic mantle and plays important roles in the …

Silicate perovskite-type phases are the most abundant constituent inside our planet and are
the predominant minerals in Earth's lower mantle more than 660 kilometers below the …

Ferromagnesian silicates are the dominant constituents of the Earth's mantle, which
comprise more than 80% of our planet by volume. To interpret the low shear-velocity …

A viscosity jump of one to two orders of magnitude in the lower mantle of Earth at 800–1,200-
km depth is inferred from geoid inversions and slab-subducting speeds. This jump is known …

Seismic anisotropy could provide vital information about the evolution and internal
convection of the deep Earth interior. Although previous seismological studies have …

Earth's transition zone at depths between 410 km and 660 km plays a key role in Earth's
deep water cycle since large amounts of hydrogen can be stored in the nominally anhydrous …