Difference between revisions of "Lin Thurber CVM"

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| [[Image:Lin_Thurber_Vp.png|256px|thumb|Lin Thurber CVM Vp Map at 0km Depth]]
 
| [[Image:Lin_Thurber_Vp.png|256px|thumb|Lin Thurber CVM Vp Map at 0km Depth]]
| [[Image:Lin_Thurber_Vs.png|256px|thumb|Lin Thurber CVM Vs Maps at 0km Depth]]
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| [[Image:Lin_Thurber_Vs.png|256px|thumb|Lin Thurber CVM Vs Map at 0km Depth]]
 
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Revision as of 05:26, 9 April 2011

Overview

The Lin Thurber et al (2010) CVM is a seismic velocity model of the California crust and uppermost mantle using a regional-scale double-difference tomography algorithm. The details are described in Lin et al. (2010). This model has been incorporated into the UCVM API.

Map views of the P-wave velocity model at 1 and 4 km depth slices. Pink dots represent relocated earthquakes. Black lines denote coast line and lakes, gray lines rivers and surface traces of mapped faults. The white contours enclose the areas where the derivative weight sum is greater than 50 (Image Credit: Guoqing Lin


Model Description

Recently, we determined the seismic velocity model of the California crust and uppermost mantle using a regional-scale double-difference tomography algorithm. Our model is the first 3D seismic velocity model for the entire state of California based on local and regional arrival time data that has ever been developed. It has improved areal coverage compared to the previous northern and southern California models, and extends to greater depth due to the inclusion of substantial data at large epicentral distances.


Projection

The UCVM API implementation of Lin-Thurber uses a geographic bilinear interpolation of the four corners of the model as a projection approximation. The four corners are:

proj_xi = -126.9210, -121.4117, -112.8281, -118.1781
proj_yi =   39.8816,   43.0597,   33.4362,   30.2581

The region is sized 1320km x 600km. The actual number of grid points along each dimension is dependant on the resolution of the Vp/Vs model. These are described below.


Digital Elevation Model

In order to query this model by depth, a state-wide DEM was constructed. The DEM is a 1320km x 600km grid with spacing of 1.0km. It was compiled by combining the NED 1 arcsec (DEM) and ETOPO2 2' (Bathymetric) datasets. The elevation at a particular lon,lat coordinate is computed by bilinear interpolation of the surrounding four points in the grid.


Vp Model

The Vp model is a 1320km x 600km x 46km grid with spacing of 10.0km along the x-y plane and variable spacing along the z axis. The z coordinate is measured as km offset from MSL, positive down. The z values contained in the model are:

-1.0, 1.0, 4.0, 8.0, 14.0, 20.0, 27.0, 35.0, 46.0

The model is published as a space-delimited text file, available from Vp Model. The model file format is a table of data values in the following format:

 FILE  FORMAT DESCRIPTION
 -117.7230    37.8242     1.00     250.00       0.00     5.0390     109.13
 lon    lat  dep   x   y   vp   DWS (derivative weight sum)

The UCVM API reads in this file directly without changes.

The Vp at a particular lon,lat coordinate is determined by trilinear interpolation of the surrounding 8 points.


Vs Model

The Vs model is a 1320km x 600km grid with spacing of 30.0km along the x-y plane and the same z-axis organization as the Vp model. The model is published as a space-delimited text file, available from Vs Model.

The model file format is the same as Vp model. The UCVM API reads in this file directly without changes.

The Vs at a particular lon,lat coordinate is determined by trilinear interpolation of the surrounding 8 points.


Density Model

The original model does not provide density values. We adopt the Nafe-Drake scaling relationship to compute density from Vp (Ludwig et al., 1970; Brocher , 2005):

rho = 1.6612*Vp - 0.4721*(Vp)^2 + 0.0671*(Vp)^3 - 0.0043*(Vp)^4 + 0.000106*(Vp)^5


Images

Lin Thurber CVM Vp Map at 0km Depth
Lin Thurber CVM Vs Map at 0km Depth

These preliminary maps are based on querying the model at a depth of 0.0m.


References

  1. Brocher, T. M. (2005), Empirical relations between elastic wavespeeds and density in the Earth's crust, Bull. Seis. Soc. Am., 95 (6), 2081-2092.
  2. Lin, G., C. H. Thurber, H. Zhang, E. Hauksson, P. Shearer, F. Waldhauser, T. M. Brocher, and J. Hardebeck (2010), A California statewide three-dimensional seismic velocity model from both absolute and differential Times, Bull. Seism. Soc. Am., 100, in press.
  3. Ludwig, W. J., J. E. Nafe, and C. L. Drake (1970), Seismic refraction, in New Concepts of Sea Floor Evolution, The Sea: Ideas and Observations on Progress in the Study of the Seas, vol. 4, edited by A. E. Maxwell, pp. 53-84, Wiley-Interscience, New York.