(c) Gabriella Alodia, Chris M. Green, Andrew M. McCaig — 2022
SWE_of_Bathymetry.m is a Matlab-based geomorphometric algorithm to obtain the numerical description of both magmatic and tectonic crust in a slow-spreading ridge through a series of calculation based on the distribution of the azimuth and plunge observed in the seafloor morphology.
Input: A gridded shipborne multibeam bathymetry (depths in metres) in *.xyz format (here: 'Input_Bathymetry_15s.xyz')
Output
- Terrain eccentricity (here: 'Output_eccentricity.xyz')
- Weight matrix: 1-sin(slope) (here: 'Output_weight.xyz')
- SWE: Slope-weighted eccentricity (here: 'Output_SWE.xyz')
- Masked SWE (here: 'Output_SWE_masked.xyz')
Each output is exported in *.xyz format. The resulting *.xyz data can be converted into *.grd using the xyz2grd function in GMT (http://gmt.soest.hawaii.edu/doc/5.3.2/xyz2grd.html)
The shipborne multibeam bathymetry data sample is downloaded from the GMRT MapTool (https://www.gmrt.org/GMRTMapTool/) with the extent xmin/xmax/ymin/ymax of -46/-44/12.5/13.15
Full paper:
Alodia, G., Green, C. M., & McCaig, A. M. (2022). SWE_of_Bathymetry.m: A geomorphometric tool to automate discrimination between detachment and magmatic seafloor at slow-spreading ridges from shipboard multibeam bathymetry, Computers & Geosciences, Volume 166, 105177. [https://doi.org/10.1016/j.cageo.2022.105177]
Preprint & EGU Presentation:
Alodia, G., Green, C., McCaig, A., & Paton, D. (2020). A novel approach for oceanic spreading terrain classification at the Mid-Atlantic Ridge using Eigenvalues of high-resolution bathymetry. In EGU General Assembly Conference Abstracts (p. 337). [https://presentations.copernicus.org/EGU2020/EGU2020-337_presentation.pdf]
Alodia, G., Green, C., McCaig, A., & Paton, D. (2020). Slope-Weighted Eccentricity: Automatic Terrain Classification of Atlantic Ocean Crust. ESSOAr: Earth and Space Science Open Archive. [https://doi.org/10.1002/essoar.10502634.1]