Roles of Hydrous Lithospheric Mantle in Deep Water Transportation and Subduction Dynamics

Abstract

We used two-dimensional simulations to investigate the effects of a hydrous lithospheric mantle (HLM) on subduction dynamics. It was demonstrated that the thickness of a subducting HLM strongly controls the motion and deformation of converging plates. When the HLM thickness is lower than a critical value, for example, ∼5 km for a 100-Ma slab, all serpentine in the HLM decomposes, and the liberated fluid enters the mantle wedge. The fluid weakens the overlying plate, causing trench retreat, rapid plate convergence, and slab stagnation. In contrast, when the HLM thickness exceeds the critical value, dense hydrous magnesium silicates appear in cold parts of the HLM at high pressures. The buoyant dense hydrous magnesium silicates reduce the slab pull force, weakening trench retreat, rapid convergence, and slab stagnation. A low HLM thickness may account for tectonics in some actual subduction zones characterized by trench retreat, rapid convergence, and stagnant slabs, for example, in Northeast Japan.