Estimation of the correlation structure of crustal velocity heterogeneity from seismic reflection data
Détails
Etat: Public
Version: Final published version
Licence: Non spécifiée
It was possible to publish this article open access thanks to a Swiss National Licence with the publisher.
ID Serval
serval:BIB_AC2AC686CCC3
Type
Article: article d'un périodique ou d'un magazine.
Collection
Publications
Institution
Titre
Estimation of the correlation structure of crustal velocity heterogeneity from seismic reflection data
Périodique
Geophysical Journal International
ISSN-L
0956-540X
Statut éditorial
Publié
Date de publication
2010
Peer-reviewed
Oui
Volume
183
Pages
1408 - 1428
Langue
anglais
Notes
Scholer2010b
Résumé
Numerous sources of evidence point to the fact that heterogeneity
within the Earth's deep crystalline crust is complex and hence may
be best described through stochastic rather than deterministic approaches.
As seismic reflection imaging arguably offers the best means of sampling
deep crustal rocks in situ, much interest has been expressed in using
such data to characterize the stochastic nature of crustal heterogeneity.
Previous work on this problem has shown that the spatial statistics
of seismic reflection data are indeed related to those of the underlying
heterogeneous seismic velocity distribution. As of yet, however,
the nature of this relationship has remained elusive due to the fact
that most of the work was either strictly empirical or based on incorrect
methodological approaches. Here, we introduce a conceptual model,
based on the assumption of weak scattering, that allows us to quantitatively
link the second-order statistics of a 2-D seismic velocity distribution
with those of the corresponding processed and depth-migrated seismic
reflection image. We then perform a sensitivity study in order to
investigate what information regarding the stochastic model parameters
describing crustal velocity heterogeneity might potentially be recovered
from the statistics of a seismic reflection image using this model.
Finally, we present a Monte Carlo inversion strategy to estimate
these parameters and we show examples of its application at two different
source frequencies and using two different sets of prior information.
Our results indicate that the inverse problem is inherently non-unique
and that many different combinations of the vertical and lateral
correlation lengths describing the velocity heterogeneity can yield
seismic images with the same 2-D autocorrelation structure. The ratio
of all of these possible combinations of vertical and lateral correlation
lengths, however, remains roughly constant which indicates that,
without additional prior information, the aspect ratio is the only
parameter describing the stochastic seismic velocity structure that
can be reliably recovered.
within the Earth's deep crystalline crust is complex and hence may
be best described through stochastic rather than deterministic approaches.
As seismic reflection imaging arguably offers the best means of sampling
deep crustal rocks in situ, much interest has been expressed in using
such data to characterize the stochastic nature of crustal heterogeneity.
Previous work on this problem has shown that the spatial statistics
of seismic reflection data are indeed related to those of the underlying
heterogeneous seismic velocity distribution. As of yet, however,
the nature of this relationship has remained elusive due to the fact
that most of the work was either strictly empirical or based on incorrect
methodological approaches. Here, we introduce a conceptual model,
based on the assumption of weak scattering, that allows us to quantitatively
link the second-order statistics of a 2-D seismic velocity distribution
with those of the corresponding processed and depth-migrated seismic
reflection image. We then perform a sensitivity study in order to
investigate what information regarding the stochastic model parameters
describing crustal velocity heterogeneity might potentially be recovered
from the statistics of a seismic reflection image using this model.
Finally, we present a Monte Carlo inversion strategy to estimate
these parameters and we show examples of its application at two different
source frequencies and using two different sets of prior information.
Our results indicate that the inverse problem is inherently non-unique
and that many different combinations of the vertical and lateral
correlation lengths describing the velocity heterogeneity can yield
seismic images with the same 2-D autocorrelation structure. The ratio
of all of these possible combinations of vertical and lateral correlation
lengths, however, remains roughly constant which indicates that,
without additional prior information, the aspect ratio is the only
parameter describing the stochastic seismic velocity structure that
can be reliably recovered.
Mots-clé
Inverse theory, Spatial analysis, Fractals and multifractals, Controlled, source seismology, Statistical seismology, Wave scattering and diffraction
Open Access
Oui
Création de la notice
25/11/2013 18:31
Dernière modification de la notice
14/02/2022 8:56
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