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1	AN ANALYSIS OF THE POTENTIAL FOR DOWNHILL SKI AREA DEVELOPMENT IN THE WHITE MOUNTAINS OF ARIZONA. Gair, Brad. January 1984 (has links) No description available.
2	Geology of the north half of the White Mountain Quadrangle, California-Nevada. Petrography of the north half of the White Mountains Quadrangle, California-Nevada / Anderson, George H. January 1933 (has links) Thesis (Ph. D.)--California Institute of Technology, 1933. / Online version available on the World Wide Web.
3	THE ROLE OF VACATION HOMES IN A RECREATION COMPLEX Czarnowski, Kenneth James, 1942- January 1973 (has links) No description available. White Mountains (Ariz.)
4	A TECHNIQUE TO IDENTIFY POTENTIAL ELK HABITAT IN THE WHITE MOUNTAINS OF ARIZONA. Kramer, Susan Spear. January 1983 (has links) No description available. Habitat (Ecology)
5	Geometry, kinematics and age of the northern half of the White Mountain shear zone, eastern California and Nevada Sullivan, Walter Andrew 27 June 2003 (has links) The White Mountain shear zone (WMSZ) is a zone of intense penetrative deformation that lies along the western front of the northern White-Inyo Range in eastern-most California and western-most Nevada. The northern half of the WMSZ is characterized by a NNE to NNW-striking steeply dipping foliation and associated shallowly plunging NNE to NW-trending stretching lineations. S-C fabrics observed in outcrop, microstructural shear sense indicators and kilometer-scale foliation geometry all indicate dextral movement. Localized discrete zones of coeval steeply plunging stretching lineations are present in the northern half of the WMSZ. Microstructural data from these domains indicate a high component of pure shear within a separate coeval kinematic framework and hence a transpressional history. The WMSZ appears to be tectonically related to both the Sierra Crest shear system to the west and the Santa Rita shear system to the south. Correlation between the WMSZ and the Santa Rita shear system indicates that Late Cretaceous dextral transpression may extend up to ~120 km along the western front of the White-Inyo Range. Cross-cutting relationships with Late Cretaceous plutons bracket the age of the WMSZ at between 72-92 Ma. A lack of annealing recrystallization in deformed quartz and the presence of high temperature crystallographic fabrics near the margins of the ca. 72 Ma Boundary Peak pluton indicate significant strain accumulation within the WMSZ subsequent to emplacement of the Boundary Peak pluton. These observations extend the duration of Late Cretaceous dextral transpression in eastern California to at least as recent as 72 Ma. / Master of Science kinematic framework shear zone transpression White Mountains
6	Management of the community economic base as a strategy for economic development Rusden, Sally Anne, 1954- January 1988 (has links) Application of economic base analysis at a multi-level scale illustrates the usefulness of this approach to tracking and measuring the economic flows and linkages between three defined areas. A census survey of employers in six rural communities of the White Mountain Region of Arizona is used to collect employment and sales data at a high level of specificity. These data serve as the basis for bifurcation of basic and nonbasic components necessary for estimating the multiplier. Measurement of these data determine the extent of economic dependence and spatial interaction which exist between communities, and between the region and the outside world. In addition, the study refines established procedures and applies a full range of adjustments to primary and secondary data sources to produce highly refined multipliers for the region and each community.
7	Simulation of fire behavior with a geographic information system Vasconcelos, Maria, 1963- January 1988 (has links) No description available. Forest fires -- Computer simulation.
8	Heterogeneous internal fabric of the Mount Barcroft pluton, White Mountains, of eastern California: an anisotropy of magnetic susceptibility study Michlesen, Karen Joyce 23 February 2004 (has links) Anisotropy of magnetic susceptibility (AMS) have been used with great success for determining the internal structure and fabrics of Jurassic and Cretaceous plutons of felsic-intermediate compositions in the White-Inyo Range of eastern California. However, application of the AMS techniques to the Mount Barcroft pluton, located in the northern White Mountains, has yielded anomalous scalar and directional AMS data indicative of unprecedented heterogeneity on the meter-kilometer scale. The 165 Ma Mount Barcroft pluton is primarily of granodiorite composition and was intruded into the Barcroft Structural Break, a northeast striking, steeply dipping structure that juxtaposes Mesozoic metavolcanic rocks to the north against Proterozoic-Paleozoic metasedimentary rocks to the south. Two oriented hand samples (A and B) were collected at each of 78 sites distributed on a 1 kilometer grid pattern across the 5 by 15 kilometer Mount Barcroft pluton and oriented cores were prepared from these hand samples for AMS analysis. Microstructure identification of single thin sections prepared for each sample site yielded primarily magmatic with minor solid-state structures. A highly heterogeneous distribution of scalar parameters (Km, P%, F%, L%, T) was documented both between sample sites and between the A and B cores at individual sites. The heterogeneity may be the result of complex mineral assemblages and the interaction between different magnetic mineral species ranging from single domain to pseudo-single domain to multidomain magnetite. More problematic are the directional parameters between A and B cores in orientation and fabric type (e.g. prolate and oblate susceptibility ellipsoids) occur which cannot be readily explained by a complex mineral assemblage. Different fabric types in A and B cores at individual sample sites could be the result of discrete, temporally unrelated, magma pulses of variable composition and viscosity. Heterogeneity of scalar and directional AMS parameters in the Mount Barcroft pluton, and its contrast with the homogeneous AMS signatures within similar age plutons to the south, may provide evidence for a previously unrecognized magma source beneath the northern White Mountains. / Master of Science AMS White Mountains heterogeneous magnetic fabrics California anisotropy of magnetic susceptibility Mount Barcroft pluton
9	Dendrochronology of Bristlecone Pine Ferguson, C. W., Graybill, D. A. 31 October 1981 (has links) "A Terminal Report Submitted 31 October, 1981 on the National Science Foundation grant EAR 78-04436 with the assistance of the Department of Energy contract no. EE-78-A-28-3274" anthropology archaeology bristlecone pine California carbon isotopes chronology climate dendrochronology geology isotopic studies pinus longaeva tree-ring White Mountains
10	Dendrochronology of Bristlecone Pine Ferguson, C. W., Graybill, D. A. 31 May 1985 (has links) "A Final Technical Report Submitted 31 May 1985 on the National Science Foundation grant EAR-8018687 for the period 1 April 1981 to 31 October 1984 with the assistance of the Department of Energy contract no. DE-AC02-81EV10680 covering the period 1 May 1981 to 31 October 1982" / Since Edmund Schulman’s initial interest in 1953, the Laboratory of Tree-Ring Research has conducted dendrochronological studies of bristlecone pine (Pinus longaeva D. K. Bailey, sp. Nov.) in the White Mountains of east-central California where living trees reach ages in excess of 4,000 years. The focus of this report relates to the support by the Geology and Anthropology sections in the National Science Foundation under grant EAR-8018687 for the period 1 April 1981 to 31 October 1984 with the assistance of the Department of Energy contract no. DE-AC02-81EV10680 covering the period 1 May 1981 to 31 October 1982. A summary of this research was recently published in Radiocarbon (Ferguson and Graybill 1983). In most cases various facets of the work were related to projects sponsored by all agencies. Therefore the full range of activities during that period is described herein. The primary project goals were: To extend the bristlecone pine chronology from the White Mountains of California beyond 6700 B.C. and strengthen it by incorporating additional specimens. To develop bristlecone pine chronologies in new areas for applications in archaeology, isotopic studies, and other earth sciences. To furnish dendrochronologically dated wood to researchers engaged in the study of past variations in carbon isotopes and climate. anthropology archaeology bristlecone pine California carbon isotopes chronology climate dendrochronology geology isotopic studies pinus longaeva tree-ring White Mountains

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