Weak magnetic field changes over the Pacific due to high conductance in lowermost mantle

TL;DR

This study uses a numerical model to show that increased conductance in the Earth's lowermost mantle under the Pacific weakens local core flows and alters flow patterns, explaining the observed low magnetic field variation in the region.

Contribution

It introduces a novel model incorporating electromagnetic coupling with a non-uniform mantle conductance to explain regional core flow variations.

Findings

Higher conductance under the Pacific weakens local core flows.

Electromagnetic drag influences flow morphology in Earth's core.

Flow deflection away from the Pacific region observed in simulations.

Abstract

For the past few centuries, the temporal variation in the Earth's magnetic field in the Pacific region has been anomalously low. The reason for this is tied to large scale flows in the liquid outer core near the core-mantle boundary, which are weaker under the Pacific and feature a planetary scale gyre that is eccentric and broadly avoids this region. However, what regulates this type of flow morphology is unknown. Here, we present results from a numerical model of the dynamics in Earth's core that includes electromagnetic coupling with a non-uniform conducting layer at the base of the mantle. We show that when the conductance of this layer is higher under the Pacific than elsewhere, the larger electromagnetic drag force weakens the local core flows and deflects the flow of the planetary gyre away from the Pacific. The nature of the lowermost mantle conductance remains unclear, but stratified core fluid trapped within topographic undulations of the core-mantle boundary is a possible explanation.