What question did this study set out to answer?

The study aims to understand how small volumes of carbonate-rich melts influence geophysical anomalies in the Earth's mantle.

February 27, 2026Open Access

Upper mantle low-velocity layer tied to volatile-charged carbonate melts

Key Points

The study aims to understand how small volumes of carbonate-rich melts influence geophysical anomalies in the Earth's mantle.
Conducted high-pressure experiments to simulate conditions of the Earth's deep interior.
Investigated the behavior of carbonate-rich melts in the presence of H2O and NaCl.
Analyzed the wetting properties and connectivity of the melts with mantle minerals.
Demonstrated that carbonate-rich melts coat surrounding mantle minerals, acting as super-spreaders.
Showed that trace amounts of melt (0.02 to 0.08 vol%) can form interconnected networks.
Facilitated melt migration enhances chemical exchange and global material recycling between Earth's surface and interior.

Abstract

Recent geophysical observations indicate the presence of small-volume, carbonate-rich melts in Earth’s deep interior. However, the mechanisms by which such minute melt fractions migrate through largely solid rocks and generate large-scale geophysical anomalies have remained unclear. Here, our high-pressure experiments demonstrate that, in the presence of H 2 O and NaCl, carbonate-rich melts act as super-spreaders, completely wetting and coating the surfaces of surrounding mantle minerals. This perfect wetting enables even trace amounts of melt (0.02 to 0.08 vol%) to form fully interconnected networks. Such connectivity facilitates efficient melt migration and chemical exchange, driving global material recycling between the surface and planetary interior.

Upper mantle low-velocity layer tied to volatile-charged carbonate melts

Key Points

Abstract

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