Deep water recycling through time

We investigate the dehydration processes in subduction zones and their implications for the water cycle throughout Earth's history. We use a numerical tool that combines thermo-mechanical models with a thermodynamic database to examine slab dehydration for present-day and early Earth settings and its consequences for the deep water recycling. We investigate the reactions responsible for releasing water from the crust and the hydrated lithospheric mantle and how they change with subduction velocity (v(s)), slab age (a) and mantle temperature (T(m)). Our results show that faster slabs dehydrate over a wide area: they start dehydrating shallower and they carry water deeper into the mantle. We parameterize the amount of water that can be carried deep into the mantle, W (×10(5) kg/m(2)), as a function of v(s) (cm/yr), a (Myrs), and T(m) (°C):[Image: see text]. We generally observe that a 1) 100°C increase in the mantle temperature, or 2) ∼15 Myr decrease of plate age, or 3) decrease in subduction velocity of ∼2 cm/yr all have the same effect on the amount of water retained in the slab at depth, corresponding to a decrease of ∼2.2×10(5) kg/m(2) of H(2)O. We estimate that for present-day conditions ∼26% of the global influx water, or 7×10(8) Tg/Myr of H(2)O, is recycled into the mantle. Using a realistic distribution of subduction parameters, we illustrate that deep water recycling might still be possible in early Earth conditions, although its efficiency would generally decrease. Indeed, 0.5–3.7 × 10(8) Tg/Myr of H(2)O could still be recycled in the mantle at 2.8 Ga. KEY POINTS: Deep water recycling might be possible even in early Earth conditions . We provide a scaling law to estimate the amount of H(2)O flux deep into the mantle . Subduction velocity has a a major control on the crustal dehydration pattern ;