Paleoseismology and seismic hazards evaluations in extensional volcanic terrains

Smith, Richard P.; Jackson, Suzette M.; Hackett, William R.

doi:10.1029/95jb01393

Cited by 39 publications

(45 citation statements)

References 71 publications

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“…Over the last 4 m.y. the post-hot spot track volcanism has been dominated by low intensity effusive basalt volcanism from 100's of widely scattered, overlapping, monogenetic shield volcanoes and northwest trending volcanic rift zones (Kuntz et al 1992;Smith et al 1996), and emplacement of scattered rhyolite cryptodomes and lava domes (e.g., McCurry et al 2008). Basalt lavas incrementally accumulated to a thickness of up to 2 km thick in the center of the ESRP.…”

Section: Regional Geologymentioning

confidence: 99%

Final Report - Assessment of Testing Options for the NTR at the INL

Howe¹,

McLing²,

McCurry³

et al. 2013

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Executive SummaryOne of the main technologies that can be developed to dramatically enhance the human exploration of space is the nuclear thermal rocket (NTR). Several studies over the past thirty years have shown that the NTR can reduce the cost of a lunar outpost, reduce the risk of a human mission to Mars, enable fast transits for most missions throughout the solar system, and reduce the cost and time for robotic probes to deep space. Three separate committees of the National Research Council of the National Academy of Sciences have recommended that NASA develop the NTR. One of the primary issues in development of the NTR is the ability to verify a flight ready unit.Three main methods can be used to validate safe operation of a NTR, after which a fully complete engine could be launched into orbit for the first full power test. The NTR testing options include 1) Full power, full duration test in an above ground facility that scrubs the rocket exhaust clean of any fission products;2) Full power , full duration test using the Subsurface Active Filtering of Exhaust (SAFE) technique to capture the exhaust in subsurface strata;3) Test of the reactor fuel at temperature and power density in a driver reactor with subsequent first test of the fully integrated NTR in space.The first method, the above ground facility, has been studied in the past [Rocketdyne, INL, MSFC]. The second method, SAFE, has been examined for application at the Nevada Test Site.The third method relies on the fact that the Nuclear Furnace series of tests in 1971 showed that the radioactive exhaust coming from graphite based fuel for the NTR could be completely scrubbed of fission products and the clean hydrogen flared into the atmosphere.Under funding from the MSFC, the Center for Space Nuclear Research (CSNR) at the Idaho National laboratory (INL) has completed a reexamination of Methods 2 and 3 for implementation at the INL site. In short, the effort performed the following:Assess the geology of the INL site and determine a location suitable SAFE testing; Perform calculations of gas transport throughout the geology; Produce a cost estimate of a non-nuclear , sub-scale test using gas injection to validate the computational models;Produce a preliminary cost estimate to build a nuclear furnace equivalent facility to test NTR fuel on a green field location on the INL site.Reexamination of Method 3, involving test of the reactor fuel in a driver reactor indicated that a new Category I facility would be required, which would cost in excess of $250M. Reexamination of Method 2, showed that the INL geology is substantially better suited to the SAFE testing method than the NTS site. The existence of impermeable interbeds just above the sub-surface aquifer ensure that no material from the test, radioactive or not, can enter the water table. Similar beds located just below the surface will prevent any gaseous products from reaching the surface for dispersion. The extremely high permeability of the basalt strata between the interbeds should allow rapid di...

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Section: Regional Geologymentioning

confidence: 99%

Final Report - Assessment of Testing Options for the NTR at the INL

Howe¹,

McLing²,

McCurry³

et al. 2013

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“…The intrusion of dikes in these rifts is a proposed mechanism to accommodate the calculated NE-SW extension of the eastern Snake River Plain aseismically (Parsons, Thompson, and Smith 1998;Smith, Jackson, and Hackett 1996). Eastern Snake River Plain rifts therefore should consist of NW-SE-trending linear rift features with multiple dikes in the subsurface aligned perpendicular to the axis of the plain, where these dikes may or may not reach the surface.…”

Section: B-21mentioning

confidence: 99%

Development Report on the Idaho National Laboratory Sitewide Three-Dimensional Aquifer Model

Wood¹,

Helm-Clark²,

Huang³

et al. 2007

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A sub-regional scale, three-dimensional flow model of the Snake River Plain Aquifer was developed to support remediation decisions for Waste Area Group 10, Operable Unit 10-08 at the Idaho National Laboratory (INL) Site. This model has been calibrated primarily to water levels and secondarily to groundwater velocities interpreted from stable isotope disequilibrium studies and the movement of anthropogenic contaminants in the aquifer from facilities at the INL. The three-dimensional flow model described in this report is one step in the process of constructing a fully three-dimensional groundwater flow and contaminant transport model as prescribed in the Idaho National Engineering and Environmental Laboratory Operable Unit 10-08 Sitewide Groundwater Model Work Plan.An updated three-dimensional hydrogeologic conceptual model is presented along with the geologic basis for the conceptual model. Sediment-dominated three-dimensional volumes were used to represent the geology and constrain groundwater flow as part of the conceptual model. Hydrological, geochemical, and geological data were summarized and evaluated to infer aquifer behavior. A primary observation from development and evaluation of the conceptual model was that relative to flow on a regional scale, the aquifer can be treated with steady-state conditions. Boundary conditions developed for the three-dimensional flow model are presented along with inverse simulations that estimate parameterization of hydraulic conductivity. Inverse simulations were performed using the pilot-point method to estimate permeability distributions. Thermal modeling at the regional aquifer scale and at the sub-regional scale using the inverted permeabilities is presented to corroborate the results of the flow model.The results from the flow model show good agreement with simulated and observed water levels almost always within 1 meter. Simulated velocities show generally good agreement with some discrepancies in an interpreted low-velocity region near the toe of the Arco Hills. This discrepancy persisted in each of the aquifer bottom thickness scenarios that were simulated precluding decisions on which aquifer bottom thickness to use in transport simulations. When joint-calibration was performed using both water levels and velocities assigned as calibration targets, the discrepancy was prevented. This result highlighted the need to consider multiple calibration objectives and not rely solely on calibration to water levels.

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“…Ruptures along dike-induced normal faults and fissures occur incrementally, as opposed to the sudden catastrophic release of strain along tectonic faults. The faults and fissures develop at shallow depths (less than 5 km) above the dike top limiting down-dip rupture widths (Smith et al 1996 [DIRS 101020], p. 6,284), in contrast to typical tectonic faults that have rupture widths extending to midcrustal levels near the brittleductile transition.…”

Section: Ground Motion From Basalt Dike Intrusionsmentioning

confidence: 99%

Development of Earthquake Ground Motion Input for Preclosure Seismic Design and Postclosure Performance Assessment of a Geologic Repository at Yucca Mountain, NV

Wong¹

2004

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performed the ground motion calculations. Richard Lee and Rajendram Arulnathan assisted in the model validation. Gabriel Toro developed the site-specific probabilistic representation of the seismic velocity profiles. Susan Olig managed the software quality assurance aspects for the study. Richard Quittmeyer, and Carl Stepp assisted in the writing of the AMR. EXECUTIVE SUMMARYThis report describes a site-response model and its implementation for developing earthquake ground motion input for preclosure seismic design and postclosure assessment of the proposed geologic repository at Yucca Mountain, Nevada. The model implements a random-vibration theory (RVT), one-dimensional (1D) equivalent-linear approach to calculate site response effects on ground motions. The model provides results in terms of spectral acceleration including peak ground acceleration, peak ground velocity, and dynamically-induced strains as a function of depth. In addition to documenting and validating this model for use in the Yucca Mountain Project, this report also describes the development of model inputs, implementation of the model, its results, and the development of earthquake time history inputs based on the model results.The purpose of the site-response ground motion model is to incorporate the effects on earthquake ground motions of (1) the approximately 300 m of rock above the emplacement levels beneath Yucca Mountain and (2) soil and rock beneath the site of the Surface Facilities Area. A previously performed probabilistic seismic hazard analysis (PSHA) (CRWMS M&O 1998a [DIRS 103731]) estimated ground motions at a reference rock outcrop for the Yucca Mountain site (Point A), but those results do not include these site response effects. Thus, the additional step of applying the site-response ground motion model is required to develop ground motion inputs that are used for preclosure and postclosure purposes.The RVT-based equivalent-linear site response model involves a computational method (i.e., equivalent-linear) that has been widely employed to evaluate 1D site response using vertically propagating plane shear (S)-waves. Departures of soil response from a linear constitutive relation are treated in an approximate manner through the use of the equivalent-linear approach. Idriss and Seed (1968 [DIRS 163520]) introduced this approach, in its present form. Basically, the approach approximates a second-order nonlinear equation, over a limited range of its variables, by a linear equation. Formally this is done in such a way that the average of the difference between the two systems is minimized. This is done in an ad-hoc manner for ground response modeling by defining an effective strain that is taken to exist for the duration of the excitation. Shear modulus reduction and hysteretic damping curves are then used to define new parameters for each layer based on the effective strain computations. The linear response calculation is repeated, new effective strains evaluated, and iterations performed until the changes in parameters are belo...

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Paleoseismology and seismic hazards evaluations in extensional volcanic terrains

Cited by 39 publications

References 71 publications

Final Report - Assessment of Testing Options for the NTR at the INL

Final Report - Assessment of Testing Options for the NTR at the INL

Development Report on the Idaho National Laboratory Sitewide Three-Dimensional Aquifer Model

Development of Earthquake Ground Motion Input for Preclosure Seismic Design and Postclosure Performance Assessment of a Geologic Repository at Yucca Mountain, NV

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