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Cyanobacteria in Kenyan Rift Valley lakes a biological and toxicological study /Ballot, Andreas. January 2004 (has links)
Berlin, Freie University, Diss., 2004. / Dateiformat: zip, Dateien im PDF-Format.
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Geologische Entwicklung im Umfeld des Mahanadi-Riftes (Indien)Fachmann, Stefan. January 2001 (has links) (PDF)
Freiberg (Sachsen), Techn. Universiẗat, Diss., 2001.
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Lake level fluctuations and Late Quaternary climate change in the Central Kenya RiftBergner, Andreas G. N. January 1900 (has links) (PDF)
Potsdam, University, Diss., 2004. / Erscheinungsjahr an der Haupttitelstelle: 2003.
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Fault Geometry and Kinematics within the Terror Rift, AntarcticaBlocher, William Burke January 2017 (has links)
No description available.
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Sediment transport and deposition across active faulted rift marginsTrout, Mark N. January 1999 (has links)
No description available.
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Modelling vector-borne diseases: epidemic and inter-epidemic activities with application to Rift Valley feverPedro, Sansao Agostinho January 2016 (has links)
A Thesis submitted to the Faculty of Science in ful lment of the requirements for the degree of Doctor of Philosophy, School of Computer Science and Applied Mathematics. Johannesburg, 2016. / In this thesis in order to study the complex dynamics of Rift Valley fever (RVF) we
combine two modelling approaches: equation-based and simulation-based modelling.
In the first approach we first formulate a deterministic model that includes two
vector populations, Aedes and Culex mosquitoes with one host population (livestock),
while considering both horizontal and vertical transmissions. An easy
applicable expression of the basic reproduction number, R0 is derived for both
periodic and non-periodic environment. Both time invariant and time varying
uncertainty and sensitivity analysis of the model is carried out for quantifying
the attribution of model output variations to input parameters over time and
novel relationships between R0 and vertical transmission are determined providing
important information useful for improving disease management.
Then, we analytically derive conditions for stability of both disease-free and endemic
equilibria. Using techniques of numerical simulations we perform bifurcation
and chaos analysis of the model under periodic environment for evaluating the
effects of climatic conditions on the characteristic pattern of disease outbreaks.
Moreover, extending this model including vectors other than mosquitoes (such as
ticks) we evaluate the possible role of ticks in the spread and persistence of the
disease pointing out relevant model parameters that require further attention from
experimental ecologists to further determine the actual role of ticks and other biting
insects on the dynamics of RVF. Additionally, a novel host-vector stochastic model
with vertical transmission is used to analytically determine the dominant period
of disease outbreaks with respect to vertical transmission efficiency. Then, novel
relationships among vertical transmission, invasion and extinction probabilities
and R0 are determined.
In the second approach a novel individual-based model (IBM) of complete mosquito
life cycle built under daily temperature and rainfall data sets is designed and
simulated. The model is applied for determining correlation between abundance of
mosquito populations and rainfall regimes and is then used for studying disease
inter-epidemic activities. We find that indeed rainfall is responsible for creating
intra- and inter-annual variations observed in the abundance of adult mosquitoes
and the length of gonotrophic cycle, number of eggs laid per blood meal, adults
age-dependent survival and
fight behaviour are among the most important features
of the mosquito life cycle with great epidemiological impacts in the dynamics of
RVF transmission. These indicators could be of great epidemiological significance
by allowing disease control program managers to focus their e orts on specific
features of vector life cycle including vertical transmission ability and diapause.
We argue that our IBM model is an ideal extendible framework useful for further
investigations of other relevant host-vector ecological and epidemiological questions
for providing additional knowledge important for improving the length and quality
of life of humans and domestic animals. / LG2017
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Lithospheric Fabric in Central North America: the Superior Province and the Mid-Continent RiftOla, Oyekunle 21 August 2014 (has links)
Seismic data from 31 seismic stations, consisting of 16 SPREE (Superior Province Rifting Earthscope Experiment) and 15 TA (Transportable Array) instruments located from 80 - 97W and 41 – 55N were used to measure the lateral variation in the lithospheric fabric beneath the Superior Province and the Mid-Continent Rift (MCR). I made shear wave splitting measurements of SK(K)S phases by using the eigenvector minimization approach of Silver and Chan (1991). Error surfaces for multiple events were stacked in back-azimuthal swaths to examine directional variability. A single anisotropic layer model is sufficient to explain my data.
My results show a high split time in the western Superior Province (WSP), very weak splits in the Nipigon Embayment and a moderate split in the eastern Superior. I observed low split times in the Penokean, Yavapai and Matzazal Provinces. A region of very low split is newly detected by this study immediately to the east of Lake Superior. The MCR shows moderate to low split times. There are subtle variations in the direction of the fast shear wave across the study region. The fast directions align with the direction of the absolute plate motion and the direction of tectonic boundaries in most regions.
Lateral variation of anisotropy and lithospheric fabric is observed across the study area. The strong fabric observed in the western Superior is truncated to its east and to its south. I interpret southward truncation to be due to the Mid-Continent Rift. My result shows that lithospheric fabric in the Nipigon Embayment (NE) located just east of the WSP has been lost or seriously modified. The NE is interpreted to be an hotspot feature, which may have initiated the MCR. Moreover, the result of this study suggests that the lithosphere in the MCR may have been thinned or modified though not as much as the lithosphere of the NE. The newly discovered localized low split zone northeast of the MCR is similar in split time and extent to the feature in the NE. The relatively weak split in the eastern Superior Province may possibly be attributed to partial loss or modification of preexisting fabric resulting from the Great Meteor hotspot track.
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A seismic study of the crust in and around the Gregory riftChukudebelu, Josiah Udemadu January 1987 (has links)
Data used for the present study were recorded at the small aperture cross-linear array station which was installed at Kaptagat (in NW Kenya) by the University of Durham. The seismic array data from local earthquakes have been analysed by velocity/azimuth filtering technique. Apparent velocities and azimuths for first and later arrival phases were measured for local rift events from the immediate east, for local events from the south west and for more distant rift events to the north and south of Kaptagat. Data from local rift events originating from the immediate east of Kaptagat were used in the present analysis to study the structure of the lithosphere beneath the Gregory rift at about 0.5 N latitude. The first arrival data (apparent velocities and azimuths) were determined to a high degree of accuracy. The first and later arrival data have been interpreted in terms of a simple two layer model with a horizontal refracting interface at a depth of 13 + 5 km and having upper and lower layer uniform velocities of 5.8 + 0.2 km/ s and7.2 + 0,2 km/s respectively. The minimum lateral extent of the top surface of this refractor is estimated at about 30 km. A maximum dip of about 6 on the interface is allowed by the data. In the preferred three layer model, a 10 km thick top horizontal layer of velocity 5.8 km/s overlies a 10 km thick intermediate layer in which velocity increases uniformly from6.0 km/s at 10 km depth to 7.5 km/s at a depth of 20 km. The intermediate layer, in turn, overlies a 7.6 km/s refractor. The models derived from the present data are consistent with the theory that upward perturbation of the lithospher asthenosphere boundary giving rise to domal uplift, lithospheric tension and magmatic activity, is the primary causeof rifting.
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Lithospheric stretching at rifted continental marginsDavis, Mark Jonathan January 1999 (has links)
No description available.
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Experimental Rift Valley feverEasterday, Bernard Carlyle, January 1961 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1961. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 183-189).
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