Geologically based model of heterogeneous hydraulic conductivity in an alluvial setting

Information on sediment texture and spatial continuity are inherent to sedimentary depositional facies descriptions, which are therefore potentially good predictors of spatially varying hydraulic conductivity (K). Analysis of complex alluvial heterogeneity in Livermore Valley, California, USA, using...

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Published in	Hydrogeology journal Vol. 6; no. 1; pp. 131 - 143
Main Authors	Fogg, Graham E., Noyes, Charles D., Carle, Steven F.
Format	Journal Article
Language	English
Published	Heidelberg Springer Nature B.V 01.06.1998
Subjects	Classifications Conductivity Debris flow Deposition Floodplains Floods Fluid flow Geology Heterogeneity Hydraulics Hydrology Levees & battures Markov analysis Markov chains Mathematical models Sedimentation & deposition Spatial distribution Texture
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Abstract	Information on sediment texture and spatial continuity are inherent to sedimentary depositional facies descriptions, which are therefore potentially good predictors of spatially varying hydraulic conductivity (K). Analysis of complex alluvial heterogeneity in Livermore Valley, California, USA, using relatively abundant core descriptions and field pumping-test data, demonstrates a depositional-facies approach to characterization of subsurface heterogeneity. Conventional textural classifications of the core show a poor correlation with K; however, further refinement of the textural classifications into channel, levee, debris-flow, and flood-plain depositional facies reveals a systematic framework for spatial modeling of K. This geologic framework shows that most of the system is composed of very low-K flood-plain materials, and that the K measurements predominantly represent the other, higher-K facies. Joint interpretation of both the K and geologic data shows that spatial distribution of K in this system could not be adequately modeled without geologic data and analysis. Furthermore, it appears that K should not be assumed to be log-normally distributed, except perhaps within each facies. Markov chain modeling of transition probability, representing spatial correlation within and among the facies, captures the relevant geologic features while highlighting a new approach for statistical characterization of hydrofacies spatial variability. The presence of fining-upward facies sequences, cross correlation between facies, as well as other geologic attributes captured by the Markov chains provoke questions about the suitability of conventional geostatistical approaches based on variograms or covariances for modeling geologic heterogeneity.[PUBLICATION ABSTRACT]
AbstractList	Information on sediment texture and spatial continuity are inherent to sedimentary depositional facies descriptions, which are therefore potentially good predictors of spatially varying hydraulic conductivity (K). Analysis of complex alluvial heterogeneity in Livermore Valley, California, USA, using relatively abundant core descriptions and field pumping-test data, demonstrates a depositional-facies approach to characterization of subsurface heterogeneity. Conventional textural classifications of the core show a poor correlation with K; however, further refinement of the textural classifications into channel, levee, debris-flow, and flood-plain depositional facies reveals a systematic framework for spatial modeling of K. This geologic framework shows that most of the system is composed of very low-K flood-plain materials, and that the K measurements predominantly represent the other, higher-K facies. Joint interpretation of both the K and geologic data shows that spatial distribution of K in this system could not be adequately modeled without geologic data and analysis. Furthermore, it appears that K should not be assumed to be log-normally distributed, except perhaps within each facies. Markov chain modeling of transition probability, representing spatial correlation within and among the facies, captures the relevant geologic features while highlighting a new approach for statistical characterization of hydrofacies spatial variability. The presence of fining-upward facies sequences, cross correlation between facies, as well as other geologic attributes captured by the Markov chains provoke questions about the suitability of conventional geostatistical approaches based on variograms or covariances for modeling geologic heterogeneity.[PUBLICATION ABSTRACT] Information on sediment texture and spatial continuity are inherent to sedimentary depositional facies descriptions, which are therefore potentially good predictors of spatially varying hydraulic conductivity (K). Analysis of complex alluvial heterogeneity in Livermore Valley, California, USA, using relatively abundant core descriptions and field pumping-test data, demonstrates a depositional-facies approach to characterization of subsurface heterogeneity. Conventional textural classifications of the core show a poor correlation with K; however, further refinement of the textural classifications into channel, levee, debris-flow, and flood-plain depositional facies reveals a systematic framework for spatial modeling of K. This geologic framework shows that most of the system is composed of very low-K flood-plain materials, and that the K measurements predominantly represent the other, higher-K facies. Joint interpretation of both the K and geologic data shows that spatial distribution of K in this system could not be adequately modeled without geologic data and analysis. Furthermore, it appears that K should not be assumed to be log-normally distributed, except perhaps within each facies. Markov chain modeling of transition probability, representing spatial correlation within and among the facies, captures the relevant geologic features while highlighting a new approach for statistical characterization of hydrofacies spatial variability. The presence of fining-upward facies sequences, cross correlation between facies, as well as other geologic attributes captured by the Markov chains provoke questions about the suitability of conventional geostatistical approaches based on variograms or covariances for modeling geologic heterogeneity.Original Abstract: Les informations sur la texture des sediments et leur continuite spatiale font partie des descriptions de facies sedimentaires de depot. Par consequent, ces descriptions sont d'excellents predicteurs potentiels des variations spatiales de la conductivite hydraulique (K). L'analyse de l'heterogeneite des alluvions complexes de la vallee de Livermore (Californie, Etats-Unis), sur la base de descriptions de carottes relativement nombreuses et de donnees d'essais de pompage, montre que l'heterogeneite souterraine peut etre caracterisee par une approche des facies de depot. Des classifications conventionnelles de la texture de la carotte montrent une correlation mediocre avec K; toutefois, une amelioration ulterieure des classifications de texture en facies de depot de chenal, de levee d'inondation, de coulee boueuse et de plaine d'inondation a fourni un cadre systematique pour une modelisation spatiale de K. Ce cadre geologique montre que le systeme est compose pour l'essentiel par des materiaux d'inondation a tres faible permeabilite; ceci laisse envisager qu'on ne peut pas supposer que K suit une distribution log-normal, sauf peut-etre a l'interieur de chaque facies. Une modelisation par chaine de Markov de la probabilite de passage, representant la correlation spatiale dans les facies et entre eux, prend en compte les faits geologiques interessants tout en fournissant une approche nouvelle pour une caracterisation statistique de la variabilite spatiale des facies. La presence de sequences a facies tronques vers le haut, d'une correlation croisee entre facies, ainsi que d'autres caracteres geologiques pris en compte par les chaines de Markov conduisent a se poser des questions sur l'adequation des approches geostatistiques conventionnelles utilisant les variogrammes ou les covariances pour modeliser l'heterogeneite geologique. Information on sediment texture and spatial continuity are inherent to sedimentary depositional facies descriptions, which are therefore potentially good predictors of spatially varying hydraulic conductivity (K). Analysis of complex alluvial heterogeneity in Livermore Valley, California, USA, using relatively abundant core descriptions and field pumping-test data, demonstrates a depositional-facies approach to characterization of subsurface heterogeneity. Conventional textural classifications of the core show a poor correlation with K; however, further refinement of the textural classifications into channel, levee, debris-flow, and flood-plain depositional facies reveals a systematic framework for spatial modeling of K. This geologic framework shows that most of the system is composed of very low-K flood-plain materials, and that the K measurements predominantly represent the other, higher-K facies. Joint interpretation of both the K and geologic data shows that spatial distribution of K in this system could not be adequately modeled without geologic data and analysis. Furthermore, it appears that K should not be assumed to be log-normally distributed, except perhaps within each facies. Markov chain modeling of transition probability, representing spatial correlation within and among the facies, captures the relevant geologic features while highlighting a new approach for statistical characterization of hydrofacies spatial variability. The presence of fining-upward facies sequences, cross correlation between facies, as well as other geologic attributes captured by the Markov chains provoke questions about the suitability of conventional geostatistical approaches based on variograms or covariances for modeling geologic heterogeneity.
Author	Noyes, Charles D Fogg, Graham E Carle, Steven F
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SubjectTerms	Classifications Conductivity Debris flow Deposition Floodplains Floods Fluid flow Geology Heterogeneity Hydraulics Hydrology Levees & battures Markov analysis Markov chains Mathematical models Sedimentation & deposition Spatial distribution Texture
Title	Geologically based model of heterogeneous hydraulic conductivity in an alluvial setting
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