Compositional heterogeneity in the mantle transition zone

Earth's mantle transition zone (MTZ) is characterized by several sharp increases in seismic wave speed between similar to 300 km and similar to 850 km depth. These seismic discontinuities are generally attributed to solid-state phase transitions that lead to density and viscosity increases, which could cause a barrier to convection by segregating thermally and chemically heterogeneous material. This Review discusses insights into the role of MTZ compositional heterogeneity in mantle convection, derived from the joint constraints of MTZ discontinuity-reflected, discontinuity-refracted and discontinuity-transmitted seismic waves and thermodynamic and convection models. Growing seismic data sets and advances in analysis techniques show that the topography of these discontinuities mainly reflects variations in mantle temperature and, hence, present-day mantle flow. However, the discordant behaviour of the 410 km and 660 km discontinuities shows that the thermal structure is not vertically coherent across the MTZ in many areas, indicating that the MTZ delays the convective transport of cold material from above and hot material from below. Variable reflectivity of the MTZ discontinuity provides evidence of lateral and vertical heterogeneity in major element chemistry and volatile content. Seismic results are consistent with whole-mantle mechanical mixing of tectonic plates, with segregated material accumulating in the MTZ over multiple mantle convection cycles.

Automated summary

This review discusses the characteristics of seismic discontinuities in the mantle transition zone (MTZ) and their impact on mantle convection. The study finds that the topography of seismic discontinuities mainly reflects variations in mantle temperature and shows features of mantle flow. However, there is incongruity in the thermal structure across the MTZ in different regions, leading to delayed transport of cold and hot material in convection. Additionally, seismic results reveal lateral and vertical heterogeneity in major element chemistry and volatile content in the MTZ.