Mass conservative three-dimensional water tracer distribution from Markov chain Monte Carlo inversion of time-lapse ground-penetrating radar data
Détails
ID Serval
serval:BIB_9318A0ADF64A
Type
Article: article d'un périodique ou d'un magazine.
Collection
Publications
Institution
Titre
Mass conservative three-dimensional water tracer distribution from Markov chain Monte Carlo inversion of time-lapse ground-penetrating radar data
Périodique
Water Resources Research
ISSN
0043-1397
Statut éditorial
Publié
Date de publication
07/2012
Volume
48
Pages
W07510
Langue
anglais
Notes
ISI:000306467100001
Résumé
Time-lapse geophysical measurements are widely used to monitor the
movement of water and solutes through the subsurface. Yet commonly used
deterministic least squares inversions typically suffer from relatively
poor mass recovery, spread overestimation, and limited ability to
appropriately estimate nonlinear model uncertainty. We describe herein a
novel inversion methodology designed to reconstruct the
three-dimensional distribution of a tracer anomaly from geophysical data
and provide consistent uncertainty estimates using Markov chain Monte
Carlo simulation. Posterior sampling is made tractable by using a
lower-dimensional model space related both to the Legendre moments of
the plume and to predefined morphological constraints. Benchmark results
using cross-hole ground-penetrating radar travel times measurements
during two synthetic water tracer application experiments involving
increasingly complex plume geometries show that the proposed method not
only conserves mass but also provides better estimates of plume
morphology and posterior model uncertainty than deterministic inversion
results.
movement of water and solutes through the subsurface. Yet commonly used
deterministic least squares inversions typically suffer from relatively
poor mass recovery, spread overestimation, and limited ability to
appropriately estimate nonlinear model uncertainty. We describe herein a
novel inversion methodology designed to reconstruct the
three-dimensional distribution of a tracer anomaly from geophysical data
and provide consistent uncertainty estimates using Markov chain Monte
Carlo simulation. Posterior sampling is made tractable by using a
lower-dimensional model space related both to the Legendre moments of
the plume and to predefined morphological constraints. Benchmark results
using cross-hole ground-penetrating radar travel times measurements
during two synthetic water tracer application experiments involving
increasingly complex plume geometries show that the proposed method not
only conserves mass but also provides better estimates of plume
morphology and posterior model uncertainty than deterministic inversion
results.
Open Access
Oui
Création de la notice
21/12/2012 15:32
Dernière modification de la notice
20/08/2019 14:55