Abstract
Abstract. Spatial gradients of tomographic velocities are seldom used in interpretation of subsurface fault structures. This study shows that spatial velocity gradients can be used effectively in identifying subsurface discontinuities in the horizontal and vertical directions. Three-dimensional velocity models constructed through tomographic inversion of active source and/or earthquake traveltime data are generally built from an initial 1-D velocity model that varies only with depth. Regularized tomographic inversion algorithms impose constraints on the roughness of the model that help to stabilize the inversion process. Final velocity models obtained from regularized tomographic inversions have smooth three-dimensional structures that are required by the data. Final velocity models are usually analyzed and interpreted either as a perturbation velocity model or as an absolute velocity model. Compared to perturbation velocity model, absolute velocity models have an advantage of providing constraints on lithology. Both velocity models lack the ability to provide sharp constraints on subsurface faults. An interpretational approach utilizing spatial velocity gradients applied to northern Cascadia shows that subsurface faults that are not clearly interpretable from velocity model plots can be identified by sharp contrasts in velocity gradient plots. This interpretation resulted in inferring the locations of the Tacoma, Seattle, Southern Whidbey Island, and Darrington Devil's Mountain faults much more clearly. The Coast Range Boundary fault, previously hypothesized on the basis of sedimentological and tectonic observations, is inferred clearly from the gradient plots. Many of the fault locations imaged from gradient data correlate with earthquake hypocenters, indicating their seismogenic nature.
Highlights
Controlled source and earthquake traveltime data are commonly used for construction of tomographic velocity models for mapping crustal structure
First arrival traveltime tomography using controlled source data from Seismic Hazards Investigation in Puget Sound (SHIPS) and regional earthquake data from British Columbia, Canada and Washington State, USA resulted in a detailed velocity model for the northern Cascadia subduction zone (Ramachandran et al, 2006)
Conventional tomographic velocity model interpretation relies on absolute velocity interpretation or perturbation velocity interpretation
Summary
Controlled source and earthquake traveltime data are commonly used for construction of tomographic velocity models for mapping crustal structure. Subsurface structures that can be mapped by tomographic velocities are generally due to varying lithology across a fault, lithology difference across basin margins and basement surfaces, and varying compaction in rocks across the fault surfaces within sedimentary units. Even though these contact/fault surfaces are in general sharp transitions in the subsurface, tomographic velocity models depict these surfaces by smooth velocity variation. Some of the structural contacts identified from velocity gradient plots show correlation with relocated earthquake positions. The gradient in the Z (depth) direction shows correlation with earthquake clusters at some fault locations much more clearly than the velocity plots
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
