The site-scale saturated zone flow model for Yucca Mountain: calibration of different conceptual models and their impact on flow paths

This paper presents several different conceptual models of the Large Hydraulic Gradient (LHG) region north of Yucca Mountain and describes the impact of those models on groundwater flow near the potential high-level repository site. The results are based on a numerical model of site-scale saturated...

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Veröffentlicht in:	Journal of contaminant hydrology 2003-04, Vol.62, p.731-750
Hauptverfasser:	Zyvoloski, George, Kwicklis, Edward, Eddebbarh, Al Aziz, Arnold, Bill, Faunt, Claudia, Robinson, Bruce A.
Format:	Artikel
Sprache:	eng
Schlagworte:	Calibration Forecasting Geological Phenomena Geology Models, Theoretical Nevada Numerical modeling Parameter estimation Permeability Radioactive Waste Refuse Disposal Saturated zone hydrology USA, Nevada, Yucca Mt Water - chemistry Water Movements Yucca Mountain
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container_title	Journal of contaminant hydrology
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creator	Zyvoloski, George Kwicklis, Edward Eddebbarh, Al Aziz Arnold, Bill Faunt, Claudia Robinson, Bruce A.
description	This paper presents several different conceptual models of the Large Hydraulic Gradient (LHG) region north of Yucca Mountain and describes the impact of those models on groundwater flow near the potential high-level repository site. The results are based on a numerical model of site-scale saturated zone beneath Yucca Mountain. This model is used for performance assessment predictions of radionuclide transport and to guide future data collection and modeling activities. The numerical model is calibrated by matching available water level measurements using parameter estimation techniques, along with more informal comparisons of the model to hydrologic and geochemical information. The model software (hydrologic simulation code FEHM and parameter estimation software PEST) and model setup allows for efficient calibration of multiple conceptual models. Until now, the Large Hydraulic Gradient has been simulated using a low-permeability, east–west oriented feature, even though direct evidence for this feature is lacking. In addition to this model, we investigate and calibrate three additional conceptual models of the Large Hydraulic Gradient, all of which are based on a presumed zone of hydrothermal chemical alteration north of Yucca Mountain. After examining the heads and permeabilities obtained from the calibrated models, we present particle pathways from the potential repository that record differences in the predicted groundwater flow regime. The results show that Large Hydraulic Gradient can be represented with the alternate conceptual models that include the hydrothermally altered zone. The predicted pathways are mildly sensitive to the choice of the conceptual model and more sensitive to the quality of calibration in the vicinity on the repository. These differences are most likely due to different degrees of fit of model to data, and do not represent important differences in hydrologic conditions for the different conceptual models.
doi_str_mv	10.1016/S0169-7722(02)00190-0
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The results are based on a numerical model of site-scale saturated zone beneath Yucca Mountain. This model is used for performance assessment predictions of radionuclide transport and to guide future data collection and modeling activities. The numerical model is calibrated by matching available water level measurements using parameter estimation techniques, along with more informal comparisons of the model to hydrologic and geochemical information. The model software (hydrologic simulation code FEHM and parameter estimation software PEST) and model setup allows for efficient calibration of multiple conceptual models. Until now, the Large Hydraulic Gradient has been simulated using a low-permeability, east–west oriented feature, even though direct evidence for this feature is lacking. In addition to this model, we investigate and calibrate three additional conceptual models of the Large Hydraulic Gradient, all of which are based on a presumed zone of hydrothermal chemical alteration north of Yucca Mountain. After examining the heads and permeabilities obtained from the calibrated models, we present particle pathways from the potential repository that record differences in the predicted groundwater flow regime. The results show that Large Hydraulic Gradient can be represented with the alternate conceptual models that include the hydrothermally altered zone. The predicted pathways are mildly sensitive to the choice of the conceptual model and more sensitive to the quality of calibration in the vicinity on the repository. 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The results are based on a numerical model of site-scale saturated zone beneath Yucca Mountain. This model is used for performance assessment predictions of radionuclide transport and to guide future data collection and modeling activities. The numerical model is calibrated by matching available water level measurements using parameter estimation techniques, along with more informal comparisons of the model to hydrologic and geochemical information. The model software (hydrologic simulation code FEHM and parameter estimation software PEST) and model setup allows for efficient calibration of multiple conceptual models. Until now, the Large Hydraulic Gradient has been simulated using a low-permeability, east–west oriented feature, even though direct evidence for this feature is lacking. In addition to this model, we investigate and calibrate three additional conceptual models of the Large Hydraulic Gradient, all of which are based on a presumed zone of hydrothermal chemical alteration north of Yucca Mountain. After examining the heads and permeabilities obtained from the calibrated models, we present particle pathways from the potential repository that record differences in the predicted groundwater flow regime. The results show that Large Hydraulic Gradient can be represented with the alternate conceptual models that include the hydrothermally altered zone. The predicted pathways are mildly sensitive to the choice of the conceptual model and more sensitive to the quality of calibration in the vicinity on the repository. These differences are most likely due to different degrees of fit of model to data, and do not represent important differences in hydrologic conditions for the different conceptual models.</description><subject>Calibration</subject><subject>Forecasting</subject><subject>Geological Phenomena</subject><subject>Geology</subject><subject>Models, Theoretical</subject><subject>Nevada</subject><subject>Numerical modeling</subject><subject>Parameter estimation</subject><subject>Permeability</subject><subject>Radioactive Waste</subject><subject>Refuse Disposal</subject><subject>Saturated zone hydrology</subject><subject>USA, Nevada, Yucca Mt</subject><subject>Water - chemistry</subject><subject>Water Movements</subject><subject>Yucca Mountain</subject><issn>0169-7722</issn><issn>1873-6009</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2003</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqFkc-OFCEQxonRuLOrj6DhZNxDa0H3QONlYzb-S9Z4cD14IjQUGUx30wKt0QfwuWV2JnqcpFLF4fdVhe8j5AmDFwyYePm5NtVIyflz4JcATEED98iG9bJtBIC6Tzb_kDNynvM3AJA99A_JGeOSdS1TG_Lndoc0h4JNtmasT1PWZAo6-jvOSP0Yf9IpOhypj4l-Xa019GNc52LC_IpWSRgqHuJMo6cueI8J50JtnC0uZTXjQZ2pmR0tOwyJhmkxttAqudu-mLLLj8gDb8aMj4_zgnx5--b2-n1z8-ndh-vXN43ppCyNVE5wNWDLW26Y84PtBuyU8GAdH0ByYD3DrlNsaGsplNxYEK7t68-3vGsvyLPD3iXF7yvmoqeQLY6jmTGuWfMeur6Xp8FqM1NCbk-DnRCtAFHB7QG0Keac0OslhcmkX5qB3keq7yLV-7w01NpHqqHqnh4PrMOE7r_qmGEFrg5AtRl_BEw624DVfxcS2qJdDCdO_AX8kbFS</recordid><startdate>20030401</startdate><enddate>20030401</enddate><creator>Zyvoloski, George</creator><creator>Kwicklis, Edward</creator><creator>Eddebbarh, Al Aziz</creator><creator>Arnold, Bill</creator><creator>Faunt, Claudia</creator><creator>Robinson, Bruce A.</creator><general>Elsevier B.V</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7ST</scope><scope>C1K</scope><scope>SOI</scope><scope>7QH</scope><scope>7TG</scope><scope>7UA</scope><scope>KL.</scope><scope>8FD</scope><scope>FR3</scope><scope>KR7</scope></search><sort><creationdate>20030401</creationdate><title>The site-scale saturated zone flow model for Yucca Mountain: calibration of different conceptual models and their impact on flow paths</title><author>Zyvoloski, George ; 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In addition to this model, we investigate and calibrate three additional conceptual models of the Large Hydraulic Gradient, all of which are based on a presumed zone of hydrothermal chemical alteration north of Yucca Mountain. After examining the heads and permeabilities obtained from the calibrated models, we present particle pathways from the potential repository that record differences in the predicted groundwater flow regime. The results show that Large Hydraulic Gradient can be represented with the alternate conceptual models that include the hydrothermally altered zone. The predicted pathways are mildly sensitive to the choice of the conceptual model and more sensitive to the quality of calibration in the vicinity on the repository. 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subjects	Calibration Forecasting Geological Phenomena Geology Models, Theoretical Nevada Numerical modeling Parameter estimation Permeability Radioactive Waste Refuse Disposal Saturated zone hydrology USA, Nevada, Yucca Mt Water - chemistry Water Movements Yucca Mountain
title	The site-scale saturated zone flow model for Yucca Mountain: calibration of different conceptual models and their impact on flow paths
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