The evolution of the Indian Ocean triple junction and the finite rotation problem /

Tapscott, Christopher Robert.

January 1979

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Earth and Planetary Sciences, 1979. / Supervised by J.G. Sclater. Vita. Includes bibliographical references.

Anomalous seismic and rheological behavior of the asthenosphere beneath oceanic and continental plates /

Weeraratne, Dayanthie Sakunthala.

January 2005

Thesis (Ph.D.)--Brown University, 2005. / Vita. Thesis advisor: Donald W. Forsyth. Includes bibliographical references (leaves 61-69, 98-103, 176-182, 224-229). Also available online.

The effects of vocabulary intervention on ninth graders' understanding of plate tectonics

Sekula, Timothy J.

January 2006

Thesis (M.S.)--Ohio University, November, 2006. / Title from PDF t.p. Includes bibliographical references.

Juan de Fuca subducting plate geometry and intraslab seismicity /

Medema, Guy Frederick.

January 2006

Thesis (Ph. D.)--University of Washington, 2006. / Vita. Includes bibliographical references (leaves 74-82).

Sedimentation between parallel plates

Paulos, Yonas Kinfu

January 1991

Settling basins can be shortened by using a stack of horizontal parallel plates which develop boundary layers in which sedimentation can occur. The purpose of this study is to examine the design parameters for such a system and to apply this approach to a fish rearing channel in which settling length is strictly limited. Flow between parallel rough and smooth plates has been modelled together with sediment concentration profile. Accurate description of boundary layer flow requires the solution of Navier-Stokes equations, and due to the complexity of the equations to be solved for turbulent flow some assumptions are made to relate the Reynolds stresses to turbulent kinetic energy and turbulent energy dissipation rate. The simplified equations are solved using a numerical method which uses the approach given by the TEACH code. The flow parameters obtained from the turbulent flow model are used to obtain the sediment concentration profile within the settling plates. Numerical solution of the sedimentation process is obtained by adopting the general transport equation. The lower plate is assumed to retain sediments reaching the bottom. The design of a sedimentation tank for a fish rearing unit with high velocity of flow has been investigated. The effectiveness of the sedimentation tank depends on the uniformity of flow attained at the inlet, and experiments were conducted to obtain the most suitable geometric system to achieve uniform flow distribution without affecting other performances of the fish rearing unit. The main difficulties to overcome were the heavy circulation present in the sedimentation tank and the clogging of the distributing system by suspended particles. Several distributing systems were investigated, the best is discussed in detail. It was concluded that a stack of horizontal parallel plates can be used in fish rearing systems where space is limited for settling sediments. Flow distribution along the vertical at the entrance to the plates determines the efficiency of the sediment settling process and a suitable geometrical configuration can be constructed to distribute the high velocity flow uniformly across the vertical. Numerical modelling of sediment removal ratio for flow between smooth and rough parallel plates has been calculated. The results show that almost the same pattern of sediment deposition occurs for both the smooth-smooth and rough-smooth plate arrangements. / Applied Science, Faculty of / Civil Engineering, Department of / Graduate

Plates (Engineering)

Plates (Engineering) -- Stability

Plate tectonics

Subduction beneath the Queen Charlotte Islands? : the results of a seismic refraction survey

Mackie, David

January 1985

The Queen Charlotte transform fault zone, which lies immediately east of the Queen Charlotte Islands, marks the boundary between the oceanic Pacific and the continental North American plates. Relative plate motions suggest that oblique underthrusting of the Pacific plate beneath North America may be presently occurring along this transform fault. To investigate this plate boundary and the implications of oblique subduction on crustal structure beneath the region, an onshore-offshore seismic refraction survey was conducted in 1983. The survey was designed to sample the crust beneath the Queen Charlotte Islands and across Hecate Strait to the mainland of British Columbia. Six ocean bottom seismographs and 11 land based stations were deployed along a 200 km line extending from 20 km west of the Queen Charlotte Islands to the mainland. Thirteen 540 kg and twenty 60 kg explosive charges were detonated along a 110 km long east-west line in the ocean to the west of the receivers. The multiple shots recorded on multiple receivers, all along the same line, effectively reverses the profile over some of its length. The objective of this study is to provide a model of the deep crustal structure beneath the fault zone, the Queen Charlotte Islands, and Hecate Strait. An exemplary subset of the extensive data set was selected to meet this objective. Beneath the deep ocean the Moho dips at about 2° to the east. At the Queen Charlotte terrace, a 25 km wide zone immediately west of the active Queen Charlotte fault, the dip of the Moho increases to about 5°. The crust is about 12 km thick at the terrace and 18 km thick at the eastern edge of the Queen Charlotte Islands, and in excess of 30 km thick at the mainland. The terrace unit itself is divided into two units - an upper unit with low velocity (4.1 km/s) and high gradient (0.3 km/s/km) and a lower unit with a high velocity (6.5 km/s) and a low gradient (0.05 km/s/km). This model, while not definitive, supports the interpretation of oblique shallow underthrusting of the Pacific plate beneath the Queen Charlotte Islands. The upper terrace unit could represent a sedimentary accretionary wedge and the lower terrace unit - the subducting slab. A model in which compression across the Queen Charlotte transform fault zone is taken up by deformation of the Queen Charlotte Islands in the form of crustal shortening and thickening is not compatible with the thin crust beneath the islands and Hecate Strait. / Science, Faculty of / Earth, Ocean and Atmospheric Sciences, Department of / Graduate

Constraining the Earth’s elastic structure with surface waves: Seismic anisotropy in the Pacific upper mantle and local amplification across the contiguous United States

Eddy, Celia Lois

January 2021

I present new models of the elastic structure of the Pacific upper mantle that address the formation and evolution of oceanic plates. Using a surface-wave dispersion dataset, I perform anisotropic tomography to construct two-dimensional phase-velocity maps and three-dimensional velocity models of the Pacific basin. My three-dimensional elastic models describe both the radial and azimuthal anisotropy of seismic waves. In order to constrain these models, I develop regularization techniques that incorporate a priori information about the nature of the oceanic upper mantle, including both the age dependence of seismic velocities and the expected scaling relationships between azimuthal anisotropy parameters derived from realistic peridotite elastic tensors. I observe a strong cooling signal in the upper-mantle seismic velocities that is consistent with halfspace cooling of the lithospheric plate; deviations from this simple cooling signature are related to the influence of mantle plumes or other thermal alteration of the lithosphere. As plate age increases, the depth to the thermally controlled lithosphere-asthenosphere boundary increases as well. This thermal boundary, as seen in the negative gradient in seismic velocities, is consistent with the depth at which there is a transition in anisotropy fast-axis orientation. This change in anisotropy orientation is due to the transition from frozen-in lithospheric anisotropy to asthenospheric anisotropy that is related to geologically recent shear beneath the base of the plate. The anisotropy orientations and strength that we observe throughout the plate are only consistent with A-type olivine fabric. There are regions where anisotropy orientations do not align with paleospreading directions in the lithosphere or absolute-plate-motion in the asthenosphere, suggesting that small-scale convection, mantle flow, and plumes could all lead to changes in the orientation of seismic anisotropy. There is a dependence on the strength of anisotropy on spreading rate at shallow depths; this implies that corner flow at faster-spreading ridges is more effective at aligning olivine crystals in the direction of shear. I also present a new set of local surface-wave amplification maps spanning the contiguous United States. I perform a synthetic-tomography experiment in order to assess our ability to resolve variations in surface-wave amplification due to variations in local elastic structure. Local amplification derived from synthetic seismograms is very highly correlated with direct predictions of amplification, suggesting that we are able to resolve this signal well and that local amplification observations reflect elastic structure local to the station on which they are measured. Local amplification can be used as a complementary constraint to phase velocity in order to map upper-mantle elastic structure.

Geophysics

Anisotropy

Plate tectonics

Seismic waves--Speed

A NEW MODEL FOR THE QUEBECIA TERRANE IN THE GRENVILLE PROVINCE AS A COMPOSITE ARC BELT: SM-ND EVIDENCE

Vautour, Shannon

20 November 2015

The Grenville Province represents a complex, highly metamorphosed orogenic belt at the southeastern margin of the Canadian Shield that is composed of different lithotectonic domains of various ages that have all been affected by the 1.0 Ga Grenville Orogeny. The present study focuses on one of the youngest regions, the Quebecia terrane, and through reconnaissance neodymium isotope mapping, investigates the extent of an old crustal block that predates the Grenville Orogeny. The Quebecia Terrane is found within Central Quebec and is a Mesoproterozoic arc terrane that was constructed around 1.5 Ga. Utilizing the Samarium-Neodymium dating method, previous research had identified a few isolated neodymium signatures of older crustal ages, and through reconnaissance mapping, several of these Paleoproterozoic crustal blocks are suggested to represent a single fragmented crustal panel. The study focused on more detailed mapping of these blocks in the areas of Baie Comeau, Forestville, Labrieville and Pipmuacan in Central Quebec. The full extent and connection between the fragments has been mapped as a series of Paleoproterozoic crustal blocks extending longitudinally through the Quebecia terrane. These blocks are embedded within the younger terrane, suggesting that the old panel was incorporated sometime during the accretion of Quebecia to Laurentia. It is possible that the old panel broke off from older Laurentian crust and reattached during the accretion of the Quebecia terrane via strike slip tectonics, implying that the Quebecia terrane itself consists of more than one accreted unit. The present study found that the older neodymium isotope signatures were consistent with the Berthe Terrane in the Manicouagan region to the north, providing evidence for the origin of the older panel within Quebecia. However, by invoking a division of Quebecia into a north and south segment, this implies a Composite Arc Belt model for the Central Grenville Province. / Thesis / Master of Science (MSc)

U-Pb geochronology of monazite and zircon in Precambrian metamorphic rocks from the Ruby Range, SW Montana: Deciphering geological events that shaped the NW Wyoming province

Jones, Carson L.

26 June 2008

No description available.

Geology

Geochronology

Radiometric Dating

Plate Tectonics

Crust and upper mantle structure of the northeastern United States

Taylor, Steven Renold

January 1980

Thesis (Ph.D.)--Massachusetts Institute of Technology, Dept. of Earth and Planetary Sciences, 1980. / Microfiche copy available in Archives and Science. / Vita. / Bibliography: leaves 226-239. / by Steven R. Taylor. / Ph.D.

Earth and Planetary Sciences.

Seismic waves

Plate tectonics