Dynamic segmentation of the Sagaing fault
Summary
The structurally simple Sagaing fault, which ruptured during the 2025 moment magnitude 7.7 Mandalay earthquake, exhibits clear dynamic segmentation despite lacking major geometric complexities. Using physics-based seismic cycle simulations, we tested the hypothesis that dynamic segmentation on the Sagaing fault is influenced by a northward increase in long-term slip rates from 18 to 28 millimeter/year. Models incorporating geodetically constrained long-term slip rates reproduced the ruptur
Content
# Dynamic segmentation of the Sagaing fault
*Published: 2026 May 7*
The structurally simple Sagaing fault, which ruptured during the 2025 moment
magnitude 7.7 Mandalay earthquake, exhibits clear dynamic segmentation despite
lacking major geometric complexities. Using physics-based seismic cycle
simulations, we tested the hypothesis that dynamic segmentation on the Sagaing
fault is influenced by a northward increase in long-term slip rates from 18 to
28 millimeter/year. Models incorporating geodetically constrained long-term slip
rates reproduced the rupture extent of historical earthquakes and the
geodetically inferred slip distribution of the 2025 mainshock. Slip rate
contrasts of 10 to 20% between adjacent segments generate sufficient
heterogeneous stress accumulation to initiate dynamic segmentation, regulating
earthquake recurrence patterns and maximum magnitudes across the fault system.
These results highlight the value of integrating geodetic, geological, and
seismological observations to improve seismic hazard assessment.
DOI: 10.1126/science.ady3237