EGU2020-8538
https://doi.org/10.5194/egusphere-egu2020-8538
EGU General Assembly 2020
© Author(s) 2021. This work is distributed under
the Creative Commons Attribution 4.0 License.

The structural architecture of the Whataroa Valley at the Alpine Fault (New Zealand) from first-arrival tomography and reflection imaging using an extended 3D VSP survey

Vera Lay1, Stefan Buske1, Sascha Barbara Bodenburg1, Franz Kleine1, John Townend2, Richard Kellett3, Martha Savage2, Douglas Schmitt4, Alexis Constantinou5, Jennifer Eccles6, Donald Lawton7, Malcolm Bertram7, Kevin Hall7, Randolph Kofman8, and Andrew Gorman9
Vera Lay et al.
  • 1TU Bergakademie Freiberg, Freiberg, Germany (vera.lay@geophysik.tu-freiberg.de)
  • 2Victoria University Wellington, Wellington, New Zealand
  • 3GNS Science, Lower Hutt, New Zealand
  • 4Purdue University, West Lafayette, United States of America
  • 5Schlumberger, Clamart, France
  • 6University of Auckland, Auckland, New Zealand
  • 7University of Calgary, Calgary, Canada
  • 8University of Alberta, Edmonton, Canada
  • 9University of Otago, Dunedin, New Zealand

The Alpine Fault along the West Coast of the South Island (New Zealand) is a major plate boundary that is expected to rupture in the next 50 years, likely as a magnitude 8 earthquake. The Deep Fault Drilling Project (DFDP) aims to deliver insight into the geological structure of this fault zone and its evolution by drilling and sampling the Alpine Fault at depth.  

Here we present results from a 3D seismic survey around the DFDP-2 drill site in the Whataroa Valley where the drillhole penetrated almost down to the fault surface. Within the glacial valley, we collected 3D seismic data to constrain valley structures that were obscured in previous 2D seismic data. The new data consist of a 3D extended vertical seismic profiling (VSP) survey using three-component receivers and a fibre optic cable in the DFDP-2B borehole as well as a variety of receivers at the surface.

The data set enables us to derive a reliable 3D P-wave velocity model by first-arrival travel time tomography. We identify a 100-460 m thick sediment layer (average velocity 2200±400 m/s) above the basement (average velocity 4200±500 m/s). Particularly on the western valley side, a region of high velocities steeply rises to the surface and mimics the topography. We interpret this to be the infilled flank of the glacial valley that has been eroded into the basement. In general, the 3D structures implied by the velocity model on the upthrown (Pacific Plate) side of the Alpine Fault correlate well with the surface topography and borehole findings.

A reliable velocity model is not only valuable by itself but it is also required as input for prestack depth migration (PSDM). We performed PSDM with a part of the 3D data set to derive a structural image of the subsurface within the Whataroa Valley. The top of the basement identified in the P-wave velocity model coincides well with reflectors in the migrated images so that we can analyse the geometry of the basement in detail.

How to cite: Lay, V., Buske, S., Bodenburg, S. B., Kleine, F., Townend, J., Kellett, R., Savage, M., Schmitt, D., Constantinou, A., Eccles, J., Lawton, D., Bertram, M., Hall, K., Kofman, R., and Gorman, A.: The structural architecture of the Whataroa Valley at the Alpine Fault (New Zealand) from first-arrival tomography and reflection imaging using an extended 3D VSP survey, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-8538, https://doi.org/10.5194/egusphere-egu2020-8538, 2020

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