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Earth Science Informatics
Published in: Earth Science Informatics 1/2015

01-03-2015 | Review Article

Harmonic coefficients of the Earth’s Spectral Crustal Model 180 – ESCM180

Authors: Wenjin Chen, Robert Tenzer

Published in: Earth Science Informatics | Issue 1/2015

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Abstract

We compile the harmonic coefficients, which describe the Earth’s crustal density structure with a spectral resolution complete to degree/order 180. These coefficients can be used in gravimetric studies of the Earth’s lithosphere structure, isostasy, crustal loading, sedimentary basins and related topics. The crustal structure of the Earth’s Spectral Crustal Model 180 (ESCM180) is separated into 9 individual layers of the topography, bathymetry, polar ice sheets, sediments (3-layers) and consolidated crust (3-layers). The harmonic coefficients describe uniformly the geometry and density (or density contrast) distribution within each individual crustal component. The topographic and bathymetric coefficients are generated from the topographic/bathymetric model ETOPO1 and the global geoid model GOCO03s. A uniform density model is adopted for the topography. The ocean density distribution is approximated by the depth-dependent seawater density model. The ETOPO1 topographic and the DTM2006.0 ice thickness data are used to generate the ice coefficients, while assuming a uniform density of the glacial ice. The geometry and density distribution within sediments is described by the 3 stratigraphic layers of a laterally varying density model, and the same structure is used to describe the density distribution within the consolidated crust down to the Moho interface. The sediment and consolidated crust coefficients are generated from the global crustal model CRUST1.0. The density contrasts of the ocean, ice, sediments and remaining crustal structures are taken relative to the reference crustal density.
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Metadata
Title
Harmonic coefficients of the Earth’s Spectral Crustal Model 180 – ESCM180
Authors
Wenjin Chen
Robert Tenzer
Publication date
01-03-2015
Publisher
Springer Berlin Heidelberg
Published in
Earth Science Informatics / Issue 1/2015
Print ISSN: 1865-0473
Electronic ISSN: 1865-0481
DOI
https://doi.org/10.1007/s12145-014-0155-5

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