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Pre-pliocene structural geology and structural evolution of the northern Los Angeles Basin, southern CaliforniaSchneider, Craig L. 08 March 1994 (has links)
Detailed subsurface structure contour maps and cross sections have shown the
northern Los Angeles basin to be underlain by a south facing monocline that is
complicated by secondary faults and folds. The monocline forms a structural shelf that
marks the northern boundary of the Los Angeles central trough. The monocline and
associated structures are called the Northern Los Angeles shelf. Isopach maps show
that during the Miocene, the predominant structural style was extension. Thick
accumulations of volcanic and volcaniclastic rocks, controlled by normal faults, had a
very different depositional pattern than during the Pliocene. At approximately the
beginning of the Pliocene extension changed to compression resulting in the
reactivation of the Miocene normal faults in a reverse sense and the beginning of the
formation of the monocline and secondary structures. Thick growth sequences were
deposited to the south of the growing monocline toward the present day Los Angeles
central trough.
Fault-bend and fault-propagation fold models are inadmissible solutions to explain
the growth of the monocline. A basement-involved shear model may explain some of
the details of the secondary structures.
Analysis of the Pliocene growth strata shows that the monocline and secondary
structures, the South Salt Lake, the East Beverly Hills, and the Las Cienegas
anticlines, all began to form near the beginning of the Pliocene. All of the secondary
structures became inactive prior to the Upper Pico during the Late Pliocene. Thick
accumulations of Upper Pico growth strata attest to continued monoclinal folding after
the secondary structures became inactive. The growth strata record both the structural
growth and the shortening associated with growth and therefore allow the dip of the
monocline causing fault or shear zone (the Monocline fault) to be calculated. In the
East Beverly Hills area, the growth strata yield a dip of 61°. At Las Cienegas the dip
of the Monocline fault is 62°. These dips are maximum values based on the
assumption the growth strata record all shortening. The fault slip rates for the
Monocline fault are similar in both areas, 1.1-1.2 mm/yr in the East Beverly Hills and
1.3-1.5 mm/yr. in Las Cienegas. The resulting horizontal convergence rates are also
similar, .5-.6 mm/yr and .6-.7 mm/yr respectively.
The Quaternary marine gravels have been deformed into a broad east-west
trending fold, the Wilshire arch. Elastic and non-elastic methods of modeling the
blind fault (Wilshire fault), over which the deformation occurred, yield much greater
shortening rates than for the Pliocene. The non-elastic method involves modeling the
arch as a fault-bend fold. This model predicts a 15° north-dipping thrust with a slip
rate of 1.5-1.9 mm/yr and a horizontal shortening rate of 1.4-1.8 mm/yr. The elastic
method involves matching the observed deformation to that produced on the free
surface by slip on a fault in an elastic half-space. The elastic dislocation model
predicts a right-lateral reverse slip solution with an oblique-slip rate of 2.6-3.3 mm/yr.
This solution yields a horizontal shortening rate of 1.4-1.8 mm/yr. These higher
shortening rates suggest that there was a marked change in tectonic style at the end of
the Pliocene from high-angle faulting and tectonic subsidence to shallow faulting and
uplift. / Graduation date: 1994
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Subsurface Quaternary and Pliocene structures of the northern Los Angeles Basin, CaliforniaHummon, Cheryl 08 March 1994 (has links)
The northern Los Angeles basin is influenced by two structural styles: the west-trending
compressional Transverse Ranges to the north, and the strike-slip Peninsular
Ranges to the south. The interaction of these two structural styles has resulted in a
complex fold/fault belt at the northern margin of the Los Angeles basin, which deforms a
variable sequence of late Miocene through Quaternary marine strata.
Subsurface mapping of Quaternary marine gravels by electric-log correlation
documents the latest phase of deformation in the northern Los Angeles basin. The
Quaternary marine gravels are folded at the Wilshire arch, the Hollywood basin, the
central trough, the Newport-Inglewood fault, and the Santa Monica fault. The west-plunging
Wilshire arch, which follows Wilshire Boulevard east of the Newport-
Inglewood fault, is a broad fold identified and named in this study. Deformation of the
Wilshire arch, which is underlain and caused by the potentially-seismogenic Wilshire
fault, began around 0.8 - 1.0 Ma. A fault-bend fold model, based on the shape of the
Wilshire arch, indicates a dip-slip rate of 1.5 - 1.9 mm/yr for the Wilshire fault, whereas
a three-dimensional elastic dislocation model indicates a right-reverse slip rate of 2.6 - 3.2
mm/year for the Wilshire fault.
The finer-grained marine Pliocene strata include the late Pliocene to early
Pleistocene Pico member, and the early Pliocene Repetto member, of the Fernando
Formation. Thickness and lithology variations in the Pico and Repetto strata, which were
influenced by syndepositional structures, indicate that the entire Pliocene and the latest
Miocene were characterized by compression. The primary structure present throughout
the Pliocene is a south-dipping monocline, which was underlain and caused by a deep
reverse fault, dipping ~55 - 60° to the north, referred to here as the Monocline fault.
Relative subsidence of the central trough resulted in deposition of up to 7000 ft (2135 m)
of Pico strata, and up to 5000 ft (1525 m) of Repetto strata, compared to zero deposition
on the monoclinal high. In the western part of the study area, the south-dipping
monocline is interrupted by the secondary East Beverly Hills fold, which may be a rabbit-ear
fold that accommodates excess volume by bedding-parallel slip. The East Beverly
Hills fold was active in the latest Miocene through Pliocene, and was most active during
early Pliocene Repetto deposition. In the eastern part of the study area, the monocline is
interrupted by the Las Cienegas fold, which formed in the hangingwall of the Las
Cienegas fault. The Las Cienegas fault was a normal fault in the late Miocene, and was
reactivated in the Pliocene as a steep reverse fault. Folding and uplift on the Las
Cienegas anticline occurred throughout the Pliocene, with the greatest amount occurring
during lower and lower-middle Pico deposition. / Graduation date: 1994
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Comparing Bulk Aerosol Profiles in the Mixed Layer in Coastal Los Angeles and the Inland EmpireWu, Taia Sean 01 January 2015 (has links)
Characteristic westerly sea breeze carries air over the Los Angeles Basin in Southern California to the Inland Empire approximately 50 miles inland, directly impacting air quality in both of these two highly polluted regions. As particles play a critical role in air quality and human health, this study compares the bulk aerosol profiles of the Los Angeles pollution "source" and Inland Empire "receptor" regions during the 2013 and 2014 NASA Student Airborne Research Program (SARP) campaigns onboard the NASA DC-8 airborne laboratory. The source and receptor regions were characterized by a series of missed approaches at the Los Angeles International Airport, Long Beach Airport, and Los Alamitos Army Airfield (coastal sources) as well as the Ontario International Airport, San Bernardino International Airport, and March Air Reserve Base (inland receptors). The aerosol populations in each region were compared, and the changes evolved were analyzed alongside volatile organic compound (VOC) concentrations from Whole Air Samples. Particle size distributions were collected using a Droplet Measurement Technologies Ultra High Sensitivity Aerosol Spectrometer (DMT-UHSAS). Aerosol concentration, mass, and mode diameter increased significantly between coastal pollution source and inland pollution receptor regions in all cases, along with an increase in mode diameter. The observed changes cannot be accounted for by aerosol aging over the Los Angeles basin alone, suggesting new particle emission/formation over this region could be a dominating factor in the changes. Positive correlations between particle increases at receptor sites and anthropogenic VOC tracers will be discussed.
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Paleocurrent Analysis of the Upper Miocene Formation, Los Angeles Basin, CaliforniaBennett, John Newton, Jr. January 1967 (has links)
Almost all sandstone beds occurring in the Upper Miocene formations at the Los Angeles basin were deposited by turbidity currents. Primary textures and structures indicative of turbidites occur in fair abundance throughout all three Upper Miocene formations. All accessible outcrops of the Puente, Modelo, and Upper Miocene portion of the Monterey and Capistrano Formations were scrutinized for sandstone beds containing primary sedimentary structures. Through study of these structures, the direction of current movement was determined. The pattern of current movement displayed reveals that sediment was being transported into the Los Angeles basin from all sides. Current directions and mineralogic studies indicate that essentially three source areas were supplying sediment into the basin. These source areas are 1) the San Gabriel Mountains, 2) an area to the east of the Santa Ana Mountains, and 3) a ridge of metamorphic rock paralleling the present coast line. The majority of sediment was derived from an area in the San Gabriel Mountains located northeast or the basin. This is evidenced by the fact that the thickness, grain size, and total sand content of the Upper Miocene units decrease southwestward across the basin.
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