A Hamilton–Jacobi Framework for Modeling Folds in Structural Geology

A Hamilton–Jacobi Framework for Modeling Folds in Structural Geology

A novel mathematical framework for modeling folds in structural geology is presented. All the main fold classes from the classical literature: parallel folds, similar folds, and other fold types with convergent and divergent dip isogons are modeled in 3D space by linear and non-linear first-order pa...

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Veröffentlicht in:Mathematical geosciences 2011-10, Vol.43 (7), p.741-761
Hauptverfasser: Hjelle, Øyvind, Petersen, Steen A.
Format: Artikel
Sprache:eng
Schlagworte:
Chemistry and Earth Sciences
Computer Science
Curvature
Differential equations
Dipping
Earth and Environmental Science
Earth Sciences
Earth, ocean, space
Exact sciences and technology
Geology
Geotechnical Engineering & Applied Earth Sciences
Hamilton-Jacobi equation
Hydrogeology
Mathematical analysis
Mathematical models
Physics
Statistics for Engineering
Stratigraphy
Structural geology
Three dimensional
Three dimensional models
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Zusammenfassung:A novel mathematical framework for modeling folds in structural geology is presented. All the main fold classes from the classical literature: parallel folds, similar folds, and other fold types with convergent and divergent dip isogons are modeled in 3D space by linear and non-linear first-order partial differential equations. The equations are derived from a static Hamilton–Jacobi equation in the context of isotropic and anisotropic front propagation. The proposed Hamilton–Jacobi framework represents folded geological volumes in an Eulerian context as a time of arrival field relative to a reference layer. Metric properties such as distances, gradients (dip and strike), curvature, and their spatial variations can then be easily derived and represented as three-dimensional continua covering the whole geological volume. The model also serves as a basis for distributing properties in folded geological volumes.
ISSN:1874-8961
1874-8953
DOI:10.1007/s11004-011-9357-2