Spelling suggestions: "subject:"klamath mountains (calif. anda Or.)"" "subject:"klamath mountains (calif. ando Or.)""
1 |
Structural, metamorphic and geochronologic constraints on the origin of the Condrey Mountain schist, north central Klamath Mountains, northern CaliforniaHelper, Mark Alan 14 July 2011 (has links)
The Condrey Mountain Schist (CMS) occupies a window through Late Triassic amphibolite facies melange in the north central Klamath Mountains in northern California and southwest Oregon. The schists owe their present level of exposure to a large structural dome centered on the Condrey Mountain Window. Transitional blueschist-greenschist facies assemblages are widespread in mafic schists in the structurally lowest levels of the window; structurally higher CMS near the window margins contains medium- to high-pressure greenschist facies parageneses. An ⁴⁰Ar/³⁹Ar crossite age indicates a late Middle Jurassic age of metamorphism. All subunits of the CMS contain evidence of progressive, polyphase deformational and metamorphic histories. The styles and geometries of minor structures in the central part of the window suggest that early folding and transposition was the result of noncoaxial deformation, and that rotational strains were replaced by irrotational flattening strains with time. Rotational strains were accompanied by the development of epidote-crossite assemblages and the growth of deerite in meta-ironstones; irrotational flattening strains were accompanied and followed by the growth of albite, actinolite, spessartine, and the Ba-silicate, cymrite. Pressure-temperature estimates, the relative ages of mineral growth and deformation, and strain geometries are consistent with, but not restricted to, a subduction zone environment. High shear strains may reflect descent and burial, whereas flattening and late, static mineral growth occur during uplift. Pressure-temperature estimates for the overlying CMS greenschists suggest temperatures similar to those in the central part of the window, but at slightly lower pressures. Thrusting of the overlying amphibolites at 150-156 Ma occurred while the amphibolites were above about 500°C. Stretching lineations indicate a movement vector of about N45W. Comparisons of the sequence and timing of metamorphic and structural events, radiometric ages, and movement directions during thrusting indicate the CMS does not represent an inlier of Klamath Western Jurassic Belt flysch but is instead an older, isolated thrust plate. Similarities with the age of metamorphism and plutonism in the overlying amphibolites suggest the two plates may be remnants of the same Middle Jurassic paired metamorphic belt. / text
|
2 |
Paleomagnetism of Jurassic plutons in the central Klamath Mountains, southern Oregon and northern CaliforniaSchultz, Karin L. 11 February 1983 (has links)
An understanding of the tectonic history of the Klamath Mountains
is crucial for a valid paleogeographic reconstruction of the Pacific
Northwest. However, prior to this study there were very few
paleomagnetic (PM) data from the Klamath Mountains (KN), which resulted
in conflicting interpretations about the role of the KM province in
the tectonic evolution of western North America. Twenty-eight sites
from five unmetamorphosed Middle Jurassic KM plutons with K-Ar ages
ranging from 161 to 139 m.y.B.P. yielded stable PM results showing
(1) a direction for the 160 in.y.B.P. Ashland pluton (D=324°, I=163°,
α₉₅=8°, n=6) nearly concordant with the coeval expected direction
(D=337°, 1=54°) and (2) clockwise rotated directions for the plutons
of Grants Pass (D=045°, I=67°, α₉₅=12°, n=4), Greyback (D=083°,I=63°,
α₉₅=9, n=9), and the Wooley Creek batholith and Slinkard pluton
combined (D=037°, 160°, α₉₅=ll°, n=9).
Tectonic interpretations of these PM data are difficult; two
interpretations are offered to explain the observed directions. In
the first, the mean PM direction of the four plutons with discordant
directions (D=057°, 1=65°, α₉₅=7°, n=22) is restored to the expected
150 m.y.B.P. (the average K-Ar age for these four plutons) direction
by rotation of a rigid block ~87° in a counterclockwise sense about a
vertical axis (the possibility of tilt of these four plutons is disregarded
in this interpretation). The Ashland pluton which shows no
rotation is problematic. Either there was (is) a tectonic boundary
west of the Ashland pluton, separating it from the rotation of the
others, or the Ashland pluton was influenced both by clockwise rotation
and tilt, the combined effect producing an essentially concordant
PM direction. In the second interpretation we distinguish
between the northern KN, intruded by the Grants Pas and Greyback
Mountain plutons, and the southern region intruded by the Wooley
Creek batholith and the Ashland and Slinkard plutons. The bases for
this distinction are recent geologic and gravity studies which
suggest that post-Middle Jurassic uplift of the domal Condrey
Mountain Schist may have caused radially outward tilt of its
adjacent terranes and plutons intruded therein, causing some of the
observed discordances in their PM directions. Thus, in the second
interpretation it is envisioned that (a) the northerly portion of
the KM, intruded by the Grants Pass and Greyback plutons, was
affected primarily by clockwise rotation about a vertical axis, and
(b) discordant directions for the remaining plutons intruded farther
south are due primarily to tilt in response to Condrey Mountain
uplift. Based on the observed inclinations, there is no evidence
of transport of the Klamath Mountain province along lines of longitude
since Middle Jurassic time.
Tectonic interpretations of the PM results of this study are
consistent with significant post-Middle Jurassic clockwise rotation
of the Klamath Mountains. The first interpretation above yields
~87° of clockwise rotation of the terrane examined. According to the
second interpretation, a clockwise rotation of ~l00° is inferred
from the average of the PM results of the northern Grants Pass and
Greyback plutons. Therefore, 10° to 25° of clockwise rotation of the
KM may have occurred prior to the formation of the Oregon Coast
Range (~55 m.y.B.P.) and the two provinces may have rotated together
since post-Lower Eocene time. / Graduation date: 1983
|
3 |
Calcium metasomatism in the Josephine peridotite, southwest OregonHarris, Raymond Charles, 1957- January 1989 (has links)
No description available.
|
4 |
Hydrothermal metasomatic banding in alpine-type peridotitesGottschalk, Richard Robert January 1979 (has links)
No description available.
|
5 |
Stratigraphy and paleontology of portions of the Klamath Mountains, CaliforniaHarbaugh, John Warvelle, January 1955 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1955. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.
|
6 |
Holocene vegetation and fire history of the floristically diverse Klamath Mountains, northern California, USABriles, Christy Elaine, 1976- 03 1900 (has links)
xiv, 227 p. : ill. (some col.) A print copy of this title is available through the UO Libraries under the call numbers: KNIGHT QE720.2.K53 B75 2008 / The Holocene vegetation and fire history of the Klamath Mountains (KM), northern California, was reconstructed at three sites based on an analysis of pollen and high-resolution macroscopic charcoal in lake-sediment cores. These data were compared with five existing records to examine regional patterns. The objective was to determine the relative importance of climate history, substrate, and disturbance regime on the development of the Klamath vegetation. In the first study, two middle-elevation sites were compared along a moisture gradient in the northern KM. The pollen data indicated a similar vegetation history, beginning with subalpine parkland in the late-glacial period, and changing to open forest in the early Holocene and closed forest in the late Holocene. However, the timing of these changes differed between sites and is attributed to the relative importance of coastal influences and topography. The second study examined the effect of substrate and nutrient limitations on the vegetation history. The pollen data suggest that ultramafic substrates (UMS), containing heavy metals and low nutrients that limit plant growth, supported drier plant communities than those on non-ultramafic substrates (NUMS) for any given period. For example, between 14,000 and 11,000 cal yr BP, cooler and wetter conditions than present led to the establishment of a subalpine parkland of Pinus monticola and/or Pinus lambertina, Tsuga, Picea on non-ultramafic substrates (NUMS). On UMS, an open Pinus jeffreyi and/or Pinus contorta woodland developed. In the early Holocene, when conditions were warmer and drier than present, open forests of Pinus monticola/lambertina , Cupressaceae, Quercus and/or Amelanchier grew on NUMS, whereas open forest consisting of Pinus Jeffreyi/contorta , Cupressaceac and Quercus developed on UMS. In the late Holocene, cool wet conditions favored closed forests of Abies, Pseudotsuga , and Tsuga on NUMS, whereas Pinus jeffreyi/contorta , Cupressaceae and Quercus forest persisted with little change on UMS. The charcoal data indicate that past fire activity was similar at all sites, implying a strong climatic control. The results of both studies suggest that the influence of Holocene climate variations, disturbance regime, and substrate type have helped create the current mosaic of vegetation in the KM. / Adviser: Cathy Whitlock, Patrick Bartlein
|
7 |
Breccia of Frog Lakes : reconstructing Triassic volcanism and subduction initiation in the east-central Sierra Nevada, CaliforniaRoberts, Sarah Elizabeth 12 March 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The Antler and Sonoma orogenies occurred along the southwest-trending passive Pacific margin of North America during the Paleozoic concluding with the accretion of the McCloud Arc. A southeast-trending sinistral transform fault truncated the continental margin in the Permian, becoming a locus for initiation of an east-dipping subduction zone creating the Sierran magmatic arc. Constrained in age between two early Triassic tuff layers, the volcanic clasts in the breccia of Frog Lakes represent one of the earliest records of mafic magmatism in the eastern Sierra Nevada. Tholeiitic rock clasts found in the breccia of Frog Lakes in the Saddlebag Lake pendant in the east central Sierra Nevada range in composition from 48% to 63% SiO2. Boninites produced by early volcanism of subduction initiation by spontaneous nucleation at the Izu-Bonin-Mariana arc are more depleted in trace element concentrations than the clasts while andesites from the northern volcanic zone of the Andes produced on crust 50 km thick have similar levels of enrichment and provide a better geochemical modern analogue. Textural analysis of the breccia of Frog Lakes suggest a subaqueous environment of deposition from a mature magmatic arc built on continental crust > 50 km thick during the Triassic. The monzodiorites of Saddlebag and Odell Lakes are temporal intrusive equivalents of the breccia of Frog Lakes and zircon geochemistry indicates a magmatic arc petrogenesis.
|
Page generated in 0.0857 seconds