A shape derivative algorithm for reconstructing elastic dislocations in geophysics

Andrea Aspri; Elena Beretta; Arum Lee; Anna L. Mazzucato

doi:10.1007/s40687-025-00501-1

A shape derivative algorithm for reconstructing elastic dislocations in geophysics

Andrea Aspri, Elena Beretta, Arum Lee, Anna L. Mazzucato

Research output: Contribution to journal › Article › peer-review

Abstract

We consider the inverse problem of determining an elastic dislocation that models a seismic fault in the quasi-static regime of aseismic, creeping faults, from displacement measurements made at the surface of Earth. We derive both a distributed and a boundary shape derivative that encodes the change in a misfit functional between the measured and the computed surface displacement under infinitesimal movements of the dislocation and infinitesimal changes in the slip vector, which gives the displacement jump across the dislocation. We employ the shape derivative in an iterative reconstruction algorithm. We present some numerical test of the reconstruction algorithm in a simplified 2D setting.

Original language	English (US)
Article number	24
Journal	Research in Mathematical Sciences
Volume	12
Issue number	2
DOIs	https://doi.org/10.1007/s40687-025-00501-1
State	Published - Jun 2025

All Science Journal Classification (ASJC) codes

Theoretical Computer Science
Mathematics (miscellaneous)
Computational Mathematics
Applied Mathematics

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10.1007/s40687-025-00501-1

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abstract = "We consider the inverse problem of determining an elastic dislocation that models a seismic fault in the quasi-static regime of aseismic, creeping faults, from displacement measurements made at the surface of Earth. We derive both a distributed and a boundary shape derivative that encodes the change in a misfit functional between the measured and the computed surface displacement under infinitesimal movements of the dislocation and infinitesimal changes in the slip vector, which gives the displacement jump across the dislocation. We employ the shape derivative in an iterative reconstruction algorithm. We present some numerical test of the reconstruction algorithm in a simplified 2D setting.",

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T1 - A shape derivative algorithm for reconstructing elastic dislocations in geophysics

AU - Aspri, Andrea

AU - Beretta, Elena

AU - Lee, Arum

AU - Mazzucato, Anna L.

N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer Nature Switzerland AG 2025.

PY - 2025/6

Y1 - 2025/6

N2 - We consider the inverse problem of determining an elastic dislocation that models a seismic fault in the quasi-static regime of aseismic, creeping faults, from displacement measurements made at the surface of Earth. We derive both a distributed and a boundary shape derivative that encodes the change in a misfit functional between the measured and the computed surface displacement under infinitesimal movements of the dislocation and infinitesimal changes in the slip vector, which gives the displacement jump across the dislocation. We employ the shape derivative in an iterative reconstruction algorithm. We present some numerical test of the reconstruction algorithm in a simplified 2D setting.

AB - We consider the inverse problem of determining an elastic dislocation that models a seismic fault in the quasi-static regime of aseismic, creeping faults, from displacement measurements made at the surface of Earth. We derive both a distributed and a boundary shape derivative that encodes the change in a misfit functional between the measured and the computed surface displacement under infinitesimal movements of the dislocation and infinitesimal changes in the slip vector, which gives the displacement jump across the dislocation. We employ the shape derivative in an iterative reconstruction algorithm. We present some numerical test of the reconstruction algorithm in a simplified 2D setting.

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A shape derivative algorithm for reconstructing elastic dislocations in geophysics

Abstract

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