# Mild-to-wild plasticity of Earth’s upper mantle

**Authors:** David Wallis, Kathryn M. Kumamoto, Thomas Breithaupt

PMC · DOI: 10.1038/s41561-026-01920-7 · 2026-02-09

## TL;DR

The Earth's upper mantle may experience sudden bursts of plastic deformation, challenging previous assumptions of smooth flow.

## Contribution

The study reveals that olivine, a key mantle mineral, exhibits intermittent wild plasticity under conditions previously thought to be stable.

## Key findings

- Olivine single crystals show intermittent displacement bursts during nanoindentation experiments.
- These bursts suggest correlated dislocation avalanches contributing ~8 ± 6% of plastic strain.
- Wild plasticity in olivine implies asthenospheric flow may be dominated by grain-scale deformation fluctuations.

## Abstract

Flow of Earth’s upper mantle has long been considered to occur by slow, near-continuous creep. This behaviour is observed in classical high-temperature deformation experiments and is a fundamental component of geodynamic models. The latest generation of high-resolution experiments, however, have revealed that materials ranging from metals to ice exhibit a spectrum of behaviours, termed mild-to-wild plasticity, that range from this mild continuous flow to intermittent wild fluctuations in plastic strain rate. Here we show, using nanoindentation experiments, that olivine exhibits measurable wildness, even under conditions at which its behaviour is expected to be relatively mild. Specifically, during experiments on olivine single crystals at room temperature, continuous plastic flow is punctuated by intermittent bursts of displacement with log-normally distributed magnitudes, indicating avalanches of correlated dislocation motion that account for ~8 ± 6% of the plastic strain. The framework of mild-to-wild plasticity predicts that wildness should increase with depth in Earth, with flow of the asthenosphere occurring almost entirely by wild fluctuations of deformation at the grain scale. The recognition of intermittent plasticity in geological materials provides additional constraints on models of dislocation-mediated flow and raises questions about the mechanisms of transient instabilities in otherwise ductile regimes, such as deep earthquakes and slow-slip events.

Flow of Earth’s upper mantle may include intermittent wild fluctuations in plastic strain rate of increasing frequency with depth, according to results of nanoindentation experiments on olivine crystals.

## Full-text entities

- **Chemicals:** ice (MESH:D007053), olivine (MESH:C034475)

## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12982119/full.md

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Source: https://tomesphere.com/paper/PMC12982119