Summary and evaluation of existing geological and geophysical data near prospective surface facilities in Midway Valley, Yucca Mountain Project, Nye County, Nevada; Yucca Mountain Site Characterization Project

Gibson, J.D.; Swan, F.H.; Wesling, J.R.; Bullard, Thomas F.; Perman, R.C.; Angell, M.; Disilvestro, L.A.

doi:10.2172/138442

Cited by 4 publications

(4 citation statements)

References 42 publications

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“…However, the vein calcretes adjacent to or within the Rainier Mesa Tuff (882,pl and 901,pl) have a flatter chondrite-normalized REE slope and a more pronounced negative Eu anomaly than the calcretes at Trench 14. This different pattern at Trench 14A has similarities to two of the different tuffs found at Trench 14A (the Rainier Mesa Tuff, sample 431,pl, that forms the hanging wall of the fault, and a n unnamed vitric nonwelded tuff within the fault, sample 88O,pl, that is part of the unit designated tb by Gibson et al 1992).…”

Section: Lanthanide Elements (Rare-earth Elements)mentioning

confidence: 56%

Petrography, mineralogy, and chemistry of calcite-silica deposits at Exile Hill, Nevada, compared with local spring deposits

Vaniman¹,

Bish²

1995

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Section: Lanthanide Elements (Rare-earth Elements)mentioning

confidence: 56%

Petrography, mineralogy, and chemistry of calcite-silica deposits at Exile Hill, Nevada, compared with local spring deposits

Vaniman¹,

Bish²

1995

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“…YuccaMountah station 29 is located east of the mountain block near the proposed location for the repository surface facilities in hole UE-25 RF#4 Figure 2). The site geology is relatively simple, with 46m of alluvium overlying 35m of nonwelded Unit 'X' tuff over the Tiva Canyon member of the Paintbrush tuff (Gibson et al, 1992). The downhole accelerometer was located 82m below the surface, just below the boundary between Unit 'Y and the Tiva Canyon.…”

Section: Station 29mentioning

confidence: 99%

“…The Tiva Canyon tuff (TCw thermal stratigraphic unit) is 1.5 W s e c ; the Yucca Mountain and Pah Canyon members (PTn thermal stratigraphic unit) are assigned 2.3 W s e c , and the two thermal stratigraphic units corresponding to the Topopah Springs member, TSwl and TSw2, are assigned velocities of 3.1 and 3.9 km/sec, respectively. The Tiva Canyon member of the Paintbrush T e which tops the hole, is quite slow where measured in Midway Valley (see Gibson et al, 1992); this is consistent with the value of 1.5 km/sec found here, The velocity of the Topopah Springs member is variable, depending on the degree of welding and lithophysal content (Spengler, Chornack Muller and Kibler, 1984), but the modeling process revealed it to be relatively homogeneous at the wavelengths sampled here, thus we differentiate only between the two major thermal stratigraphic units. The model for station 28 appears in Figure 15 25,27), however the overall level of radial ground motion predicted by the transfer function is quite consistent with the observations.…”

Section: Station 28mentioning

confidence: 99%

Near-surface velocity modeling at Yucca Mountain using borehole and surface records from underground nuclear explosions

Durrani

Walck

1996

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Borehole and d a c e recordings of Nevada Test Site nuclear explosions provide the only data available for characterization of ground motions at the potential repository depth at Yucca Mountain. Triaxial accelerometer pairs were located from 1980 to 1990 at four boreholes in the Yucca Mountain area; three of these boreholes are aligned in a northsouth profile traversing the potential repository (with downhole instrumentation at 350-375 m depth) while the fourth was located near the suggested site for the associated surface facilities (instrumentation at 82m depth). Thirty-seven nuclear tests recorded at these locations have yielded 86 surfacddownhole data pairs usefd for modeling nearsurface seismic structure.We have used the propagator matrix method of calculating the fill plane wave response for body waves incident on a layered structure to develop synthetic onedimensional transfer functions for each of the four borehole stations. The velocity models used for calculating the transfer finctions are based on available geologic, seismologic, and well-log information for Yucca Mountain, and were developed using forward modeling. The transfer h c t i o n is the ratio of the spectral response at the depth of the downhole instrument to that at the surface instrument. Convolution of the transfer function with the actual surface seismogram yields a synthetic downhole record that is compared to the data. The modeling process results in one-dimensional velocity models for the four borehole locations. We used the models for the three stations in the northsouth profile to construct a two-dimensional velocity model for the uppermost 350m of Yucca Mountain. While none of the boreholes intersect the potential repository, the twodimensional model provides a means to predict motions at the actual repository location and depth for a specified sudkce seismogram... ll DISCLAIMERPortions of this document may be illegible in electronic image products. Images are produced from the best available original document. DISCLAIMERThis report was prepared as an account of work sponsored by an agency of the United States Government. Neither the United States Government nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, rnanuf'acturer, or otherwise does not necessarily constitute or imply its endorsement, mommendation, or favoring by the United States Government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States Government or any agency thereof. This work was supported by the United States Department of Energy under Contract DE-ACO4-94AL85000 and was prepared under the Yucca Mountain Site Characteri...

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“…The rock magnetic properties of the TC Tuff are documented by abundant published data (Egli & Lowrie, ; Jackson et al, ; Rosenbaum, , ; Rosenbaum & Rivers, ; Rosenbaum & Snyder, ; Schlinger et al, , ; Till et al, ; Worm & Jackson, ), and the geologic setting of the TC Tuff has been extensively studied due to its proximity to the potential nuclear waste repository at Yucca Mountain (Buesch et al, ; Flint et al, ; Frizzell & Shulters, ; Gibson et al, ; Istok et al, ; Levy et al, ; Moyer et al, ; Rautman & Engstrom, ). In this paper, we present the first paleointensity results from the basal vitric zone TC Tuff, as well as previously unpublished rock magnetic results from two new sections.…”

Section: Introductionmentioning

confidence: 99%

Absolute Paleointensity Study of Miocene Tiva Canyon Tuff, Yucca Mountain, Nevada: Role of Fine‐Particle Grain‐Size Variations

Abdulghafur

Bowles

2019

Geochem Geophys Geosyst

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Fine-grained, Ti-poor titanomagnetite in the~12.7 Ma Tiva Canyon (TC) Tuff systematically increases in grain size from superparamagnetic (SP) at the flow base to single domain (SD) at a few meters height. This allows us to examine the role of grain-size variation on paleointensity, within the transition from SP to stable SD. We present magnetic properties from two previously unreported sections of the TC Tuff, as well as Thellier-type paleointensity estimates from the lowermost~7.0 m of the flow. Magnetic hysteresis, frequency-dependent susceptibility, and thermomagnetic data show that sample grain-size distribution is dominated by SP in the lower~3.6 m, transitioning upwards to mostly stable SD. Paleointensity results are closely tied to stratigraphic height and to magnetic properties linked to domain state. SD samples have consistent absolute paleointensity values of 28.5 ± 1.94 μT (VADM of 51.3 ZAm 2 ) and behaved ideally during paleointensity experiments. The samples including a significant SP fraction have consistently higher paleointensities and less ideal behavior but would likely pass many traditional quality-control tests. We interpret the SD remanence to be a primary thermal remanent magnetization but discuss the possibility of a partial thermal-chemical remanent magnetization if microcrystal growth continued at T < T c and/or the section is affected by post-emplacement vapor-phase alteration. The link between paleointensity and domain state is stronger than correlations with water content or other evidence of alteration and suggests that the presence of a significant SP population may adversely impact paleointensity results, even in the presence of a stable SD fraction. Plain Language SummaryThe strength-or intensity-of Earth's magnetic field changes over geologic time, and these changes are important in learning about the internal evolution and processes of Earth's core. These "paleointensity" variations are recorded in many Earth materials, including volcanic ash flows, sometimes called "tuffs." Magnetic minerals in these flows acquire a magnetization proportional to Earth's field strength when they cool. The approximately 12 million-year-old Tiva Canyon Tuff in the western United States contains very fine-grained magnetite particles, the size of which increases upwards from the base of the flow. This small size is typically considered ideal for a paleointensity recorder, and the systematic size variation allows us to test effect of grain size on the paleointensity estimation across the lower end of the size spectrum. Samples collected from the lowermost 7 m of the Tiva Canyon Tuff were subjected to laboratory experiments designed to recover paleointensity. We find that the smallest particles perform poorly in the experiments and do not produce consistent results, while the slightly larger particles perform ideally and provide a consistent answer. This tells us that smaller is not always better, and there is a very narrow grain size range that will produce accurate results.

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Summary and evaluation of existing geological and geophysical data near prospective surface facilities in Midway Valley, Yucca Mountain Project, Nye County, Nevada; Yucca Mountain Site Characterization Project

Cited by 4 publications

References 42 publications

Petrography, mineralogy, and chemistry of calcite-silica deposits at Exile Hill, Nevada, compared with local spring deposits

Petrography, mineralogy, and chemistry of calcite-silica deposits at Exile Hill, Nevada, compared with local spring deposits

Near-surface velocity modeling at Yucca Mountain using borehole and surface records from underground nuclear explosions

Absolute Paleointensity Study of Miocene Tiva Canyon Tuff, Yucca Mountain, Nevada: Role of Fine‐Particle Grain‐Size Variations

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