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16 July 2004
S-wave velocity structure beneath the Kaapvaal Craton from surface-wave inversions
compared with estimates from mantle xenoliths
Angela Marie Larson
M.S. defense
16 July 2004
16 July 2004
Acknowledgments
I would like to thank my advisor, Arthur Snoke, as well as my committee members, David James and Martin Chapman
Thanks also go to the VT Geosciences Dept for their support as well as the Aubrey E. Orange Award
I think an eternal debt is owed to Connie and Richard for always making things go a little more smoothly
Thanks to all of my friends and associates in the dept
A special thank you goes to Brian, Laura O, and my animal family for your support (I know I can be hard to deal with…)
16 July 2004
This presentation compares two methods for calculating the S-wave velocity structure of the Kaapvaal Craton
Where and Who? Study area and previous work
What? Conclusions
How? Xenoliths, surface waves, inversions
Why? The purpose behind the study
Oh my!
16 July 2004
The purpose of this research is to:
Calculate the S-wave velocity structure of the Kaapvaal Craton using surface waves
This slide is for Maddy!
Compare xenolith analysis and surface-wave analysis for the upper-mantle velocity structure
Look for the existence of a low-velocity zone beneath the Archean craton using synthetics
16 July 2004
The region contains almost 1 Ga of Archean history and has remained largely unaltered since its formation
Political boundaries Geologic provinces
16 July 2004
The Southern African Seismic Experiment collected seismic data in a dense (1º spacing) array
There were 79 stations deployed for a minimum of 1 year
16 July 2004
The Kaapvaal Project researchers also performed geochemical/petrologic studies on local xenoliths
Approximately 100 on-craton samples with ages ~90 Ma were analyzed geothermobarometrically
16 July 2004
Kimberlite pipes are for more than just diamonds; some can be analyzed for their records of mantle properties
http://www.amnh.org/exhibitions/diamonds/
The procedure of analyzing mantle xenoliths for upper mantle seismic structure has not been utilized much…yet
16 July 2004
The Kaapvaal xenoliths provide a snapshot of seismic velocities and density for the craton at ~90 Ma
The xenoliths studied were emplaced in the southern half of the craton
16 July 2004
The xenolith results indicate a slight decreasing trend in S-wave velocities for the applicable depth range
The xenoliths reflect seismic velocities and density for a depth range of 50 to 180 km.
16 July 2004
The surface-wave data is selected by choosing well-recorded earthquakes
The earthquake must be large enough to record in the array with a reasonable signal-to-noise ratio
Favorable earthquakes had epicenters with great-circle paths passing through the NE and SW quadrants of the array
These earthquakes must cross continent-ocean boundaries and mid-ocean ridges (if applicable) at near-normal incidence
16 July 2004
Five events were used for study
There were four events near the coast of central Chile and one in Iran. Their great-circle paths to the center of the array are shown
16 July 2004
Frequency-time analysis helps with the selection of a range of useful periods and frequencies
A range for this event would be 3.40 - 4.05 km/s and about 25 - 180 seconds
16 July 2004
Station pairs have their own selection criteria
No more than 3º difference in backazimuths
At least 200 km between stations
Well-recorded at both stations
16 July 2004
The Bushveld Complex appears to affect the velocity structures of the Kaapvaal Craton
To work with “pure” craton, I excluded all station pairs with interstation paths within the Bushveld
16 July 2004
I found 16 paths from the five events using the selection criteria
Several events use the same station pair and some events use collinear paths
16 July 2004
“The velocity with which an observable, individual wave or wave crest is propagated through a medium”
The phase velocities are calculated for many (or all) of the periods over a range to make a dispersion curve
16 July 2004
A dispersion curve was calculated for each of the 16 different event/paths
The solid line on the left is the dispersion curve calculated from the xenolith-based model
16 July 2004
The 16 sets were combined into a single composite curve and compared with the xenolith-based curve
The curve fits the data very well, and this is a pre-inversion result
16 July 2004
The Neighbourhood Algorithm (NA) is used to find an ensemble of models that fit a chosen misfit criterion
The NA is a non-linear direct search method. The search results are not limited to a single maximum
16 July 2004
The misfit criterion was essentially a standard deviation with the potential for a penalty to be assessed
The penalty is designed to cause physically-unlikely models to be thrown out
16 July 2004
There were eight non-independent parameters arranged over the depth range for the model
All solution models were constrained to match the reference model values for velocities greater then 400 km
16 July 2004
After 10,000 model iterations, 1,788 models fit within the misfit cutoff of 0.015
This selected misfit allowed for enough potential models that their dispersion curves visually filled the space of the error bars
16 July 2004
Between the “best” model and an “average” model, I chose the average model
The best model had the smallest overall misfit, but it is a physically less likely model
16 July 2004
To test for uniqueness, I compared the xenolith-based results with those from different reference models
These global models are not plausible for continental shields. The dispersion curves produced from the unaltered models don’t fit
16 July 2004
After inversions performed by the NA, models are found that have reasonable fits to the original seismic data
The gentle reverse “s”-curves are a result of the fewer parameters of NA and from using reference models that were so unlikely
16 July 2004
The results are that the xenolith-derived results match the seismic-derived S-wave velocity model
The region of most interest is from 50 to 180 km depth
16 July 2004
I ran synthetic tests to check for evidence of a low-velocity zone (LVZ)
The SYNTH model was made by perturbing the XNLTH model; a LVZ was put in starting at 180 km depth.
16 July 2004
An NA inversion run produced acceptable models that fit the SYNTH generated dispersion velocities
There is no LVZ starting at 180 km depth --- the models are significantly different
16 July 2004
In summary
The xenolith analysis and surface-wave analysis agree for the upper-mantle velocity structure
This means that the geotherm of the Kaapvaal Craton is almost the same today as it was 90 Ma
16 July 2004
And
There is no LVZ starting at 180 km depth or less beneath the Kaapvaal craton
Therefore, either there is a significant tectonic root and the LVZ is deeper than 180 km or low velocities and low viscosities are not closely correlated