Elastic Properties of Thermally Treated Diabase and Peridotite: Implications Toward the Elastic Properties of Oceanic Lithosphere

Supported by laboratory experimental results, the reduction in elastic thickness () and flexural rigidity () at trench outer rise, which enables bending, is attributed to damage. A series of laboratory experiments were performed on intact and thermally treated diabase and peridotite (400 degrees C-800 degrees C) under increasing confining pressures (3-200 MPa) at room temperature. Simultaneous porosity and elastic wave velocity (P and S) measurements were obtained under dry and fluid saturated conditions. The velocity and porosity inversions indicated a significant variation in crack properties (crack density, aspect ratio) and reduction in Young's modulus, of thermally treated samples in comparison to the intact samples. Hence the experimental results suggested weakening in elastic properties of a damaged oceanic lithosphere. Subsequently created lithospheric strength profiles showed a strength reduction in wet models in comparison to dry models. Under the assumption of different cooling models, the aging of the plate resulted in an increase in strength with deeper neutral zones. The outcome of the strength profiles was utilized to estimate T-e and D, which are also dependent on the elasticity of the lithosphere. The results showed a reduction in D with increasing damage and suggest that the bending at the subduction zone is facilitated by weakened elastic properties of a damaged lithosphere. While most of the geophysical observations of T-e were able to be constrained by the proposed damaged models, some shallow observations indicated enhanced damage triggered either by increased depth to brittle-ductile transition or by large bending related faulting events.

Automated summary

Supported by laboratory experiments, the study shows that the reduction in elastic thickness and flexural rigidity at trench outer rise is attributed to damage. The experiments on intact and thermally treated samples found a significant variation in crack properties and reduction in Young's modulus of the thermally treated samples, indicating weakening in elastic properties of a damaged oceanic lithosphere. The created lithospheric strength profiles suggest a reduction in strength in wet models compared to dry models, and the bending at the subduction zone is facilitated by weakened elastic properties of a damaged lithosphere.