Alluvial fans thesis /

Hooke, Roger LeB.

January 1965

Thesis (Ph. D.)--California Institute of Technology, 1965. / Includes bibliographical references (leaves 189-192).

Alluvial fans. Alluvial fans

A random-walk simulation model of alluvial-fan deposition

Price, W. E.

January 1972

Thesis (Ph. D. - Hydrology and Water Resources)--University of Arizona. / Includes bibliographical references.

Alluvial fans

Genesis of typic paleorthids and petrocalcic paleargids on the same fan terrace in the Avra Valley near Tucson, Arizona

Levine, Steven Joel.

January 1985

Thesis (M.S. - Soil and Water Science)--University of Arizona, 1985. / Includes bibliographical references (leaves 90-93).

Soils Soils Alluvial fans Alluvial fans

Delineating debris-flow hazards on alluvial fans in the Coromandel and Kaimai regions, New Zealand, using GIS : a thesis submitted in partial fulfilment of the requirements for the degree of Master of Science in Environmental Science at the University of Canterbury /

Welsh, Andrew J.

January 2007

Thesis (M. Sc.)--University of Canterbury, 2007. / Typescript (photocopy). Includes bibliographical references (leaves 150-169). Also available via the World Wide Web.

Debris avalanches Alluvial fans

A RANDOM-WALK SIMULATION MODEL OF ALLUVIAL-FAN DEPOSITION

Price, Williams Evans, Jr.

06 1900

A digital model based on a random walk was used in an experiment to determine how well such a model is able to simulate alluvial - fan deposition. The model is in three dimensions and is dynamic with respect to both time and space. Two principal stochastic events were employed, (1) a relative uplift of the mountain area that is the source of the fan sediments, and (2) a storm event of sufficient magnitude to result in the deposition of material on the fan. These two events are assumed to follow independent Poisson processes with exponentially distributed interoccurrence times. The pattern of deposition is determined by a random walk from the canyon mouth at the mountain front, and each depositional event is assumed to occur instantaneously. The direction that each step in the walk takes is determined probabilistically by the gradient in the direction of flow, the momentum of flow, and the boundary conditions stipulated in the model. The type of flow, whether a depositing debris or water flow, or eroding water flow, depends upon the thickness of erodible material in the source basin. Deposition is assumed to occur over the entire route of flow either as a bed tapered in the direction of flow or as a bed of uniform thickness. The particle -size distribution of the water -flow deposits is governed by the slope in the direction of flow. Erosion is considered negative deposition and results from the exponential decline in elevation of the main stream channel at the fan apex during periods of no uplift, or from water flows containing little basin sediment. Results from the computer runs were printed as geologic maps of the fan surface, and geologic sections through the deposits; these indicate that, at least qualitatively, a random -walk model provides a reasonable basis for simulating alluvial -fan deposition.

Alluvial fans -- Mathematical models.

An investigation of the hazard associated with the alluvial fans on the Kaikoura Coast, South Island, New Zealand : a thesis submitted to the Victoria University of Wellington in fulfilment of the requirements for the degree of Master of Science (Honours) in Physical Geography /

Baylis, Erin Julia.

January 2009

Thesis (M.Sc.(Hons.))--Victoria University of Wellington, 2009. / Includes bibliographical references.

A random-walk simulation model of alluvial-fan deposition.

Price, W. E.(William Evans),1924-

January 1972

A digital model based on a random walk was used in an experiment to determine how well such a model is able to simulate alluvial-fan deposition. The model is in three dimensions and is dynamic with respect to both time and space. Two principal stochastic events were employed, (1) a relative uplift of the mountain area that is the source of the fan sediments, and (2) a storm event of sufficient magnitude to result in the deposition of material on the fan. These two events are assumed to follow independent Poisson processes with exponentially distributed interoccurrence times. The pattern of deposition is determined by a random walk from the canyon mouth at the mountain front, and each depositional event is assumed to occur instantaneously. The direction that each step in the walk takes is determined probabilistically by the gradient in the direction of flow, the momentum of flow, and the boundary conditions stipulated in the model. The type of flow, whether a depositing debris or water flow, or eroding water flow, depends upon the thickness of erodible material in the source basin. Deposition is assumed to occur over the entire route of flow either as a bed tapered in the direction of flow or as a bed of uniform thickness. The particle-size distribution of the water-flow deposits is governed by the slope in the direction of flow. Erosion is considered negative deposition and results from the exponential decline in elevation of the main stream channel at the fan apex during periods of no uplift, or from water flows containing little basin sediment. Results from the computer runs were printed as geologic maps of the fan surface, and geologic sections through the deposits; these indicate that, at least qualitatively, a random-walk model provides a reasonable basis for simulating alluvial-fan deposition.

Hydrology.

Alluvial fans -- Mathematical models.

Depositional environments, basin evolution and tectonic significance of the Eocene Chumstick Formation, Cascade Range, Washington /

Evans, James Erwin.

January 1988

Thesis (Ph. D.)--University of Washington, 1988. / Vita. Bibliography: leaves [236]-254.

The influence of growing structures on Cretaceous alluvial systems along the Cordilleran thrust belt front, Valley of Fire, Southern Nevada

McNamara, Kelsey Caitlin.

January 1900

Thesis (MS)--Montana State University--Bozeman, 2009. / Typescript. Chairperson, Graduate Committee: James G. Schmitt. Includes bibliographical references (leaves 110-122).

The geology of alluvial fans in Arizona

Blissenbach, Erich Bertram Karl, 1924-

January 1951

No description available.

Alluvial fans -- Arizona.

Geology -- Arizona.

maps