Groundwater Flow and Thermal Modeling to Support a Preferred Conceptual Model for the Large Hydraulic Gradient North of Yucca Mountain
The purpose of this study is to report on the results of a preliminary modeling framework to investigate the causes of the large hydraulic gradient north of Yucca Mountain. This study builds on the Saturated Zone Site-Scale Flow and Transport Model (referenced herein as the Site-scale model (Zyvoloski, 2004a), which is a three-dimensional saturated zone model of the Yucca Mountain area. Groundwater flow was simulated under natural conditions. The model framework and grid design describe the geologic layering and the calibration parameters describe the hydrogeology. The Site-scale model is calibrated to hydraulic heads, fluid temperature, and groundwater flowpaths. One area of interest in the Site-scale model represents the large hydraulic gradient north of Yucca Mountain. Nearby water levels suggest over 200 meters of hydraulic head difference in less than 1,000 meters horizontal distance. Given the geologic conceptual models defined by various hydrogeologic reports (Faunt, 2000, 2001; Zyvoloski, 2004b), no definitive explanation has been found for the cause of the large hydraulic gradient. Luckey et al. (1996) presents several possible explanations for the large hydraulic gradient as provided below: The gradient is simply the result of flow through the upper volcanic confining unit, which is nearly 300 meters thick near the large gradient. The gradient represents a semi-perched system in which flow in the upper and lower aquifers is predominantly horizontal, whereas flow in the upper confining unit would be predominantly vertical. The gradient represents a drain down a buried fault from the volcanic aquifers to the lower Carbonate Aquifer. The gradient represents a spillway in which a fault marks the effective northern limit of the lower volcanic aquifer. The large gradient results from the presence at depth of the Eleana Formation, a part of the Paleozoic upper confining unit, which overlies the lower Carbonate Aquifer in much of the Death Valley region. The Eleana Formation is absent at borehole UE-25 p#1 at Yucca Mountain, which penetrated the lower Carbonate Aquifer directly beneath the lower volcanic confining unit. The Site-scale model uses an area of very low permeability, referenced as the east-west barrier, to simulate the large hydraulic gradient. The Site-scale model is further refined in this study to provide a base-case model for exploring the geologic causes of the large hydraulic gradient.
- Research Organization:
- Nevada System of Higher Education (NSHE), University of Nevada, Las Vegas (UNLV)
- Sponsoring Organization:
- USDOE - Office of Civilian Radioactive Waste Management (RW)
- DOE Contract Number:
- FC28-04RW12232
- OSTI ID:
- 921093
- Report Number(s):
- DOE/RW12232-5NQ-018; ORD-FY04-018; TRN: US0800967
- Country of Publication:
- United States
- Language:
- English
Similar Records
Deep Resistivity Structure of Rainier Mesa-Shoshone Mountain, Nevada Test Site, Nevada
Conceptualization of the Predevelopment Groundwater Flow System and Transient Water-Level Responses in Yucca Flat, Nevada National Security Site, Nevada
Related Subjects
54 ENVIRONMENTAL SCIENCES
AQUIFERS
BOREHOLES
CALIBRATION
CARBONATES
DESIGN
HYDRAULICS
PERMEABILITY
SIMULATION
SPILLWAYS
TRANSPORT
WATER
YUCCA MOUNTAIN
Yucca Mountain
Nevada
Saturated Zone Site-Scale Flow and Transport Model
hydraulic gradient
groundwater
model