Stratigraphic and structural characteristics of volcanic rocks in core hole USW G-4, Yucca Mountain, Nye County, Nevada

Spengler, R.W.; Chornack, Michael P.; Muller, D.C.; Kibler, J.E.

doi:10.3133/ofr84789

Cited by 25 publications

(31 citation statements)

References 19 publications

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“…Test samples were representative of the massive, nonwelded ash flow tuffs of Calico Hills that are pervasively zeolitized within portions of the Yucca Mountain block. All test samples contain approximately 75 % clinoptilolite, 15 % cristobalite, and lesser amounts of quartz, smectite, and alkali feldspar [Spengler and Chornack, 1984;Bish and Chipera, 1989]. The clinoptilolites in the test samples are of a mixed Na-K-Ca type with the alkalic ions dominating the exchangeable cation content (Table 1).…”

Section: Sample Preparation and Expepdmental Methodsmentioning

confidence: 99%

Hydration swelling effects on time‐dependent deformation of zeolitized tuff

Blacic¹

1993

J. Geophys. Res.

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Long‐duration creep deformation experiments were performed on zeolitized tuffs from Yucca Mountain, Nevada, at temperatures of 35°–75°C, confining pressure of 5 MPa, and water pore pressure of 0.1 MPa. The test samples were initially loaded to a relatively small fraction of the uniaxial compressive failure stress, and allowed to creep; then the stress was increased periodically until creep failure occurred. The strain versus time creep curves exhibit the classical phenomenological phases of primary, secondary, and tertiary creep analogous to those for ductile metals, although the tuffs deform by dilational microcracking and fail by brittle fracture. Mechanical “steady state” or secondary creep strain rates as low as 1 × 10−10 s−1 were observed in the tests. Tertiary creep axial failure strains averaged about 6 × 10−3. The early, water saturation phases of the tests are characterized by large hydration swelling strains associated with water absorption by the zeolite minerals in the tuffs. The hydration was often incomplete after one month of immersion, and slow, continued hydration affected the creep curves so that the samples appeared to lengthen against axial differential stresses as high as 55 MPa. This strong chemical‐mechanical coupling suggests that in situ hydration state changes could generate stresses of similar magnitude.

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Section: Sample Preparation and Expepdmental Methodsmentioning

confidence: 99%

Hydration swelling effects on time‐dependent deformation of zeolitized tuff

Blacic¹

1993

J. Geophys. Res.

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“…Borehole U SW G-4 (hereafter referred to as G-4), located in the north central part of Yucca Mountain, was drilled to a depth of 915 m during 1982, passing through the same section penetrated by borehole G-3 and terminating in the upper part of the Tram Member of the Crater Flat Tuff [Spengler and Chornack, 1984]. Thin intercepts of the Yucca Mountain and Pah Canyon members of the Paintbrush Tuff were also encountered.…”

Section: Description Of Boreholesmentioning

confidence: 98%

“…It is rare that a macroscopically observed geological feature such as degree of welding correlates so well with a physical measurement. Because it has such a fundamental control on porosity, the degree of welding also influences other geological parameters such as alteration and fracturing [Scott and Castellanos, 1984;Spengler and Chornack, 1984]. Zeolitic alteration occurs more frequently in the nonwelded and poorly welded samples.…”

Section: Degree Of Weldingmentioning

confidence: 99%

Physical properties of ash flow tuff from Yucca Mountain, Nevada

Nelson¹,

Anderson²

1992

J. Geophys. Res.

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We have measured the density and determined the porosity of 198 samples of ash flow tuffs from three boreholes at Yucca Mountain, Nevada. The electrical properties, velocity, and permeability of many of these samples have also been determined. We use mineralogical and physical data from other sources to determine the dependence of measured physical properties upon petrology. Porosity in the samples varies over a wide range, from as low as 1% in the densely welded tuffs to 53% in the zeolitized nonwelded tuffs. Porosity is the primary control on the other measured physical properties that consequently vary over broad ranges. Alteration (zeolites and clays) is a primary control on grain density and a significant secondary control on bulk density, resistivity, velocity, and permeability. Sorting the samples into rock classes defined in terms of the degree of welding and gross mineralogy enables us to separate the influence of zeolites and clays from that of porosity. Empirical rock property relationships established for sandstones can be applied with good success to tuffs. Archie's law relating resistivity to porosity is found to fit the unaltered samples with an exponent m of 2.0. An empirical expression relating compressional velocity to porosity and clay content forms an excellent upper bound to the velocity-porosity data. Permeability-porosity plots are similar in form to those obtained for clastic rocks, although the permeability is considerably lower than in clastic rocks of similar porosity. Zeolites and clays reduce the grain density, increase the electrical conductivity, reduce the compressional velocity, and reduce the permeability. tained in boreholes in Rainier Mesa on the northern extremity of NTS. A series of reports [Carroll and Magner, 1988; Carroll, 1989, 1990] describes the measurement difficulties, presents the borehole logs, and discusses the physical properties of volcanic tuffs at Rainier Mesa.

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“…Fractures at Yucca Mountain are generally coated or filled to some extent at all depths, down to and below the water table [Sykes et al, !979;Spengler et al, 1984;Carlos, 1985; Crowe and Vaniman, 1985; Carlos, 1987]. The mineralogy, thickness, and amount and uniformity of coverage of fracture coatings are highly variable and uncertain.…”

mentioning

confidence: 99%

“…Whereas some fractures appear to have no coating, others are completely coated or filled. Typical coatings include manganese oxides, manganates, iron oxides, iron hydroxides, silica, zeolites, smectites, or carbonates [Spengler et al, 1984;Carlos, 1985]. If the hydrologic properties of these mineral-ized coatings are much different than the matrix rock, the coatings could have a significant impact on the capillary uptake of water by the matrix from the fracture.…”

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confidence: 99%

Impact of fracture coatings on fracture/matrix flow interactions in unsaturated, porous media

Thoma¹,

Gallegos²,

Smith³

1992

Water Resources Research

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Groundwater flow in unsaturated, fractured rock is often assumed to be dominated by the porous matrix component. This is frequently the result of reasoning that water flowing in the fractures is rapidly imbibed into the rock matrix by capillary suction forces with negligible resistance to uptake at the fracture/matrix interface. However, the existence of a low‐permeability mineralized layer or coating at this interface may substantially reduce matrix imbibition and could consequently result in fracture‐dominated flow. To test this idea, four tuff samples containing natural fractures were obtained from tuff formations in southern Nevada. By performing imbibition experiments into the matrix rock, across a mineralized fracture face and then across a fresh uncoated fracture face, water uptake as a function of time and coating was measured. A model combining Darcy's law and the Washburn equation has been used to describe the imbibition behavior. Before testing the tuff samples, the experimental technique and imbibition model were first tested using ordered sphere packings with known pore size and structure. From the tuff imbibition data, the ratio of the permeability through the mineralized face to the permeability through the uncoated face was found to be 0.3 (relatively little effect of the mineralized layer) for two samples, 0.01 for one sample, and 10−7 (uptake strongly restricted by the mineralized layer) for one sample. Using a simple fracture flow model and the imbibition model mentioned above to simulate matrix uptake from the fracture, numerical simulations indicate that the existence of fracture coatings could significantly decrease the travel time and increase the travel depth of water flowing through fractures.

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Stratigraphic and structural characteristics of volcanic rocks in core hole USW G-4, Yucca Mountain, Nye County, Nevada

Cited by 25 publications

References 19 publications

Hydration swelling effects on time‐dependent deformation of zeolitized tuff

Hydration swelling effects on time‐dependent deformation of zeolitized tuff

Physical properties of ash flow tuff from Yucca Mountain, Nevada

Impact of fracture coatings on fracture/matrix flow interactions in unsaturated, porous media

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