Seismic gap breached by the 2025 Mw 7.7 Mandalay (Myanmar) earthquake
Bo Li, Sigurjón Jónsson, Cahli Suhendi, Jihong Liu, Duo Li, Arthur Delorme, Yann Klinger, P. Martín
Abstract
Seismic gaps are fault sections that have not hosted a large earthquake for a long time compared to neighbouring segments, making them likely sites for future large events. The 2025 Mw 7.7 Mandalay (Myanmar) earthquake, on the central section of the Sagaing Fault, ruptured through a known seismic gap and ~160 km beyond it, resulting in an exceptionally long rupture of ~460 km. Here we investigate the rupture process of this event and the factors that enabled it to breach the seismic gap by integrating satellite synthetic aperture radar observations, seismic waveform back-projection, Bayesian finite-fault inversion and dynamic rupture simulations. We identify a two-stage earthquake rupture comprising initial bilateral subshear propagation for ~20 s followed by unilateral supershear rupture for ~70 s. Simulation-based sensitivity tests suggest that the seismic gap boundary was not a strong mechanical barrier in terms of frictional strength, and that nucleation of the earthquake far from the gap boundary, rather than its supershear speed, allowed the rupture to outgrow the gap and propagate far beyond it. Hence, we conclude that the dimension of seismic gaps may not reflect the magnitude of future earthquakes. Instead, ruptures may cascade through multiple fault sections to generate larger and potentially more damaging events. The 2025 Mw 7.7 Mandalay earthquake in Myanmar breached and propagated beyond a long-quiescent segment owing to a mechanically weak barrier at the segment boundary and distant nucleation, according to seismic, geodetic and numerical analyses.