Detached Tonga slab in the mantle transition zone imaged by stress variations of deep-focus earthquakes

Tonga is a part of Tonga-Kermadec, the 2,550 km long subduction system in SW Pacific. It represents a convergent plate boundary and the outcome of the Pacific plate submerging underneath the Australian plate. The Tonga slab subducts steeply into the mantle and is the fastest converging and the most seismically active deep subduction system in the world. In the mantle transition zone, especially at depths greater than 500 km, the geometry of the slab becomes complex, forming separated slab segments. Moreover, it undergoes strong deformation and sharp bending in the north, which results in significantly different course of the southern and northern Tonga slab.

We focused on the mantle transition zone in the southern part of Tonga (south of latitude 22°S). We performed stress analysis by inverting focal mechanisms of deep earthquakes available in the Global Centroid Moment Tensor catalog. We focused on depths ranging from 400 to 680 km, where seismic activity forms two subparallel bands of events, in the west and east. We revealed two distinct stress regimes that characterize this deep Tonga double seismic zone and distinguish two slab segments. The stress orientation in the eastern slab segment matches the down-dip compressional stress regime of the subducting slab. However, the stress orientation of the western slab segment is different, with the maximum compression in the vertical direction. This suggests that the western slab segment is no longer connected to the subducting slab. Such findings are also supported by the horizontal westward detachment of the western slab segment at 520 km depth and by substantially different fault orientations in both slab segments. This points not only to the retention of the southern Tonga slab in the mantle transition zone but also to its detachment at the base of the upper mantle with a remnant slab no longer connected to the younger actively subducting slab.