Abstract
In recent years, there has been an increase in the deployment of
relatively dense arrays of seismic stations. The availability of
spatially densely sampled global and regional seismic data has
stimulated the adoption of industry-style imaging algorithms applied to
converted- and scattered-wave energy from distant earthquakes, leading
to relatively high-resolution images of the lower crust and upper
mantle. We use seismic interferometry to extract reflection responses
from the coda of transmitted energy from distant earthquakes. In theory,
higher-resolution images can be obtained when migrating reflections
obtained with seismic interferometry rather than with conversions,
traditionally used in lithospheric imaging methods. Moreover, reflection
data allow the straightforward application of algorithms previously
developed in exploration seismology. In particular, the availability of
reflection data allows us to extract from it a velocity model using
standard multichannel data-processing methods. However, the success of
our approach relies mainly on a favourable distribution of earthquakes.
In this paper, we investigate how the quality of the reflection response
obtained with interferometry is influenced by the distribution of
earthquakes and the complexity of the transmitted wavefields. Our
analysis shows that a reasonable reflection response could be extracted
if (1) the array is approximately aligned with an active zone of
earthquakes, (2) different phase responses are used to gather adequate
angular illumination of the array and (3) the illumination directions
are properly accounted for during processing. We illustrate our analysis
using a synthetic data set with similar illumination and source-side
reverberation characteristics as field data recorded during the
2000-2001 Laramie broad-band experiment. Finally, we apply our method to
the Laramie data, retrieving reflection data. We extract a 2-D velocity
model from the reflections and use this model to migrate the data. On
the final reflectivity image, we observe a discontinuity in the
reflections. We interpret this discontinuity as the Cheyenne Belt, a
suture zone between Archean and Proterozoic terranes.
Original language | English |
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Pages (from-to) | 339-357 |
Journal | Geophysical Journal International |
Volume | 183 |
Publication status | Published - 2010 |
Keywords
- Image processing
- Interferometry
- Body waves
- Crustal structure