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Racial Discrimination and the Psychology Well-Being of Black and Latinx Children: School is (not always) a Safe Space2019 August 1900 (has links)
archives@tulane.edu / 1 / Veronica Coriano
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Optical Characterization of Quantum-Dots-in-a-Well Infrared Photodetectors Under External PerturbationsCervantes Chia, Carlos Andres, Lewandowska, Weronika Maria January 2008 (has links)
<p>In this project we have used Fourier transform infrared spectroscopy to study the photoresponse of two different types of quantum dot-in-a-well infrared photodetectors (DWELL QDIPs). The basic task was to compare the photoresponse of these two detectors, and to study the influence of external resonant laser pumping on the photoresponse. Series of measurements were done at 77K. In the first measurements we investigated the photoresponse for different applied voltages at 77K. </p><p>In a second run of experiments, we used a 1064 nm infrared semiconductor laser to resonantly </p><p>pump the fundamental transition of the quantum dots. The results show that by using this </p><p>additional illumination the photoresponse was dramatically increased by creating additional </p><p>charge carriers in the quantum dots. This could be used to increase the sensitivity of infrared </p><p>detectors based on QDs.</p>
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The Relationship between Ethnic Identity and Psychological Health: A Meta-Analytic ReviewGrant, Julie Hewatt 30 September 2008 (has links)
Ethnic identity, or one's feelings of belongingness and affirmation with one's ethnic group, has been postulated to be related to one's psychological health. Specifically, it is thought that stronger ethnic identity is related to better psychological health. In order to fully investigate this relationship, a meta-analytic review and analysis was conducted utilizing all previous research on the relationship between ethnic identity and psychological health. This study sought to examine this relationship in more detail by dividing psychological health into two areas: 1) psychological functioning, and 2) psychological dysfunction. Both of these categories were examined and analyzed separately utilizing a random effects model. Results indicated a significant relationship between ethnic identity and psychological health. Additionally, ethnic identity was shown to be significantly and inversely related to psychological dysfunction. Several moderators (age, gender, publication status, type of ethnic identity measure, ethnic group membership) were tested for their respective effects on these relationships. For ethnic identity and psychological health, several variables moderated this relationship, including publication status, ethnic identity measure, and ethnic group membership. For ethnic identity and psychological dysfunction, the following variables moderated the relationship: age, gender, ethnic identity measure, and ethnic group membership. Limitations, implications, and future directions are discussed.
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Ultrapdeep water blowouts: COMASim dynamic kill simulator validation and best practices recommendationsNoynaert, Samuel F. 17 February 2005 (has links)
The petroleum industry is in a constant state of change. Few industries have advanced as far technologically as the petroleum industry has in its relatively brief existence. The produced products in the oil and gas industry are finite. As such, the easier to find and produce hydrocarbons are exploited first. This forces the industry to enter new areas and environments to continue supplying the world's hydrocarbons. Many of these new frontiers are in what is considered ultradeep waters, 5000 feet or more of water. While all areas of the oil and gas industry have advanced their ultradeep water technology, one area has had to remain at the forefront: drilling. Unfortunately, while drilling as a whole may be advancing to keep up with these environments, some segments lag behind. Blowout control is one of these areas developed as an afterthought. This lax attitude towards blowouts does not mean they are not a major concern. A blowout can mean injury or loss of life for rig personnel, as well as large economic losses, environmental damage and damage to the oil or gas reservoir itself. Obviously, up-to-date technology and techniques for the prevention and control of ultradeep water blowouts would be an invaluable part of any oil and gas company's exploration planning and technology suite. To further the development of blowout prevention and control, COMASim Cherokee Offshore, MMS, Texas A&M Simulator) was developed. COMASim simulates the planning and execution of a dynamic kill delivered to a blowout. Through a series of over 800 simulation runs, we were able to find several key trends in both the initial conditions as well as the kill requirements. The final phase of this study included a brief review of current industry deepwater well control best practices and how the COMASim results fit in with them. Overall, this study resulted in a better understanding of ultradeep water blowouts and what takes to control them dynamically. In addition to this understanding of blowouts, COMASim's strengths and weaknesses have now been exposed in order to further develop this simulator for industry use.
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Cement fatigue and HPHT well integrity with application to life of well predictionUgwu, Ignatius Obinna 15 May 2009 (has links)
In order to keep up with the world’s energy demands, oil and gas producing companies have taken the initiative to explore offshore reserves or drill deeper into previously existing wells. The consequence of this, however, has to deal with the high temperatures and pressures encountered at increasing depths.
For an oil well to maintain its integrity and be produced effectively and economically, it is pertinent that a complete zonal isolation is achieved during well completion. This complete zonal isolation can be compromised due to factors that come into play when oil well cement experiences cyclic loading conditions which can lead to fatigue failure as a consequence of extensive degradation of the microstructure of the cement material depending on stress levels and number of cycles. There have been a lot of research and experimental investigations on the mechanism of fatigue failure of concrete structures but the fatigue behavior of oil well cement is still relatively unknown to engineers. Research in the area of oil well cement design has led to improved cement designs and cementing practices but yet many cement integrity problems persist and this further strengthens the need to understand the mechanism of cement fatigue.
This research seeks to develop a better understanding of the performance of the casing cement bond under HPHT well conditions that can lead to best practices and a model to predict well life. An analytical model, which can be used to evaluate stresses in the cement sheath based on actual wellbore parameters, was developed and combined effectively with finite element models to evaluate the fatigue and static loading behavior of a well.
Based on the findings of this investigation, the mechanical properties of the casing, cement and formation as well loading conditions play a very big role in the static and fatigue failure of well cement.
Finally, recommendations for future work on this subject were also presented in order to understand all tenets of cement fatigue and to develop governing equations.
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Resonant optical nonlinearities in cascade and coupled quantum well structuresXie, Feng 15 May 2009 (has links)
Resonant or near resonant optical nonlinearities in semiconductor coupled
quantum-well systems are discussed. Quantum engineered coupled or cascade quantumwell
structures can provide giant nonlinear susceptibilities for various optical nonlinear
processes. Nonlinearities integrated within quantum cascade lasers (QCL) showed great
potential in various applications in the infrared range. Several schemes of nonlinearities
are proposed and discussed in this work.
Integrating difference frequency generation (DFG) with QCL can yield long
wavelength radiation, such as terahertz light. The DFG process does not require
population inversion at a transition associated with low photon energy; however, this
requirement is necessary to lasers, such as QCL, and is hard to meet, because of the
thermal backfilling and inefficient injection or pumping at room temperature. Therefore
terahertz radiation due to DFG QCL for room temperature is proposed. On the other
hand, the second harmonic generation can double laser frequency, and then push
radiation frequency of AlInAs/GaInAs/InP based QCL to short wavelengths such as 3
μm and shorter. Optical nonlinearities can extend working frequencies of light sources, and also
can help to improve light detection. For example, a sum frequency generation can upconvert
mid/far-IR signal into near-IR signal with strong near-IR pump light, namely
high efficient near-IR photon detector could be employed to detect mid/far-IR light. A
specific designed quantum well structure of this frequency up-conversion scheme is
discussed.
A scheme of monolithic in-plane integration of the optical nonlinearities with
QCL is also proposed. In this scheme, an optical nonlinear section is made from the
same quantum well structure of a QCL, and is under an independent applied bias. Due to
the independence of the applied bias, the nonlinearities can be tuned flexibly. In
particular, a widely tunable Raman laser based on this scheme could be achieved.
A frequency up-conversion based on sum frequency generation process in
coupled quantum-well structure is also proposed for mid-infrared detection. By
converting mid-IR signal to near-IR, superior near-IR detector such as silicon avalanche
photo diode (APD) can be employed. The scheme can provide lower noise equivalent
power (NEP) or higher detectivity compared with regular semiconductor photo detectors.
A scheme of lasing without inversion (LWI) based on QCL for THz radiation is
proposed. A ladder type three-level system for LWI process is integrated into a boundto-
continue high power QCL at 10 μm. The proposed LWI generates THz signal at 69
μm. An optical gain about 80 cm-1 is achieved, against a waveguide loss about 30 cm-1 in
a semi insulator (SI) surface plasmon waveguide.
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Horizontal Well Placement Optimization in Gas Reservoirs Using Genetic AlgorithmsGibbs, Trevor Howard 2010 May 1900 (has links)
Horizontal well placement determination within a reservoir is a significant and difficult
step in the reservoir development process. Determining the optimal well location is a
complex problem involving many factors including geological considerations, reservoir
and fluid properties, economic costs, lateral direction, and technical ability. The most
thorough approach to this problem is that of an exhaustive search, in which a simulation
is run for every conceivable well position in the reservoir. Although thorough and
accurate, this approach is typically not used in real world applications due to the time
constraints from the excessive number of simulations.
This project suggests the use of a genetic algorithm applied to the horizontal well
placement problem in a gas reservoir to reduce the required number of simulations. This
research aims to first determine if well placement optimization is even necessary in a gas
reservoir, and if so, to determine the benefit of optimization. Performance of the genetic
algorithm was analyzed through five different case scenarios, one involving a vertical well and four involving horizontal wells. The genetic algorithm approach is used to
evaluate the effect of well placement in heterogeneous and anisotropic reservoirs on
reservoir recovery. The wells are constrained by surface gas rate and bottom-hole
pressure for each case.
This project's main new contribution is its application of using genetic algorithms to
study the effect of well placement optimization in gas reservoirs. Two fundamental
questions have been answered in this research. First, does well placement in a gas
reservoir affect the reservoir performance? If so, what is an efficient method to find the
optimal well location based on reservoir performance? The research provides evidence
that well placement optimization is an important criterion during the reservoir
development phase of a horizontal-well project in gas reservoirs, but it is less significant
to vertical wells in a homogeneous reservoir. It is also shown that genetic algorithms are
an extremely efficient and robust tool to find the optimal location.
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Evaluation of Collector Well Configurations to Model Hydrodynamics in Riverbank Filtration and Groundwater RemediationDe Leon, Tiffany Lucinda 2010 August 1900 (has links)
Collector well designs are necessary to maximize groundwater uptake and riverbank filtration without negatively impacting an aquifer. Unfortunately, there is a lack of information and research regarding the implementation of collector well design parameters. In the past, collector well installation was too costly, but recent advances in well technology have made collector wells more cost effective. This research will contribute a set of guidelines to optimize riverbank filtration and groundwater remediation. This study models the hydrodynamics surrounding collector well configurations in riverbank filtration and groundwater remediation. Visual Modflow® was utilized to run a variety of numerical models to test four areas: flux along the laterals of a collector well, collector well interactions with a river, collector well yield, and collector well remediation capability. The two design parameters investigated were lateral length (25 m, 50 m, and 100 m) and number of laterals (3 and 4).
The lateral flux tests confirm flux increases towards the terminal end of each lateral and pumping rate is the controlling factor in flux amount obtained along the laterals. The analysis of the flux-river interaction shows the main factor in determining flux amount is the initial river geometry, followed by the pumping rate, regional background flow, and collector well design, respectively. The models suggest that the 4-lateral collector well design is more effective than the 3-lateral design and in addition, 100 meter length laterals provide the highest amount of yield with the least amount of drawdown. The remediation tests investigate the application of vertical well equations to evaluate collector well designs in two areas: minimum pumping rate to capture line source of particles and first arrival time of particles. The remediation models show 100 meter length laterals provide both the lowest pumping rate and the highest residence time with the surrounding aquifer for maximum remediation. Ultimately, these models provide basic design guidelines and explain which designs are most effective, depending on the collector well purpose.
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Studies in AlxGa1-xSb/InAs Quantum Well at Low Temperature and High Magnetic FieldYu, Chung-Yin 09 July 2001 (has links)
We intend to study the magneto-transport properties of two dimensional electron-hole systems in the condition of ultra-low temperature and high magnetic field by SdH measurement and QHE measurement. In these samples, the SdH oscillations show a 2DEG behavior. We observed that the sample shows negative persistent photoconductivity effect at low temperature and high field under illumination. We want to compare with results before 4 years, so we change more sets of measurement. And we want to know if these samples still show the same effect after 4 years.
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Ultrapdeep water blowouts: COMASim dynamic kill simulator validation and best practices recommendationsNoynaert, Samuel F. 17 February 2005 (has links)
The petroleum industry is in a constant state of change. Few industries have advanced as far technologically as the petroleum industry has in its relatively brief existence. The produced products in the oil and gas industry are finite. As such, the easier to find and produce hydrocarbons are exploited first. This forces the industry to enter new areas and environments to continue supplying the world's hydrocarbons. Many of these new frontiers are in what is considered ultradeep waters, 5000 feet or more of water. While all areas of the oil and gas industry have advanced their ultradeep water technology, one area has had to remain at the forefront: drilling. Unfortunately, while drilling as a whole may be advancing to keep up with these environments, some segments lag behind. Blowout control is one of these areas developed as an afterthought. This lax attitude towards blowouts does not mean they are not a major concern. A blowout can mean injury or loss of life for rig personnel, as well as large economic losses, environmental damage and damage to the oil or gas reservoir itself. Obviously, up-to-date technology and techniques for the prevention and control of ultradeep water blowouts would be an invaluable part of any oil and gas company's exploration planning and technology suite. To further the development of blowout prevention and control, COMASim Cherokee Offshore, MMS, Texas A&M Simulator) was developed. COMASim simulates the planning and execution of a dynamic kill delivered to a blowout. Through a series of over 800 simulation runs, we were able to find several key trends in both the initial conditions as well as the kill requirements. The final phase of this study included a brief review of current industry deepwater well control best practices and how the COMASim results fit in with them. Overall, this study resulted in a better understanding of ultradeep water blowouts and what takes to control them dynamically. In addition to this understanding of blowouts, COMASim's strengths and weaknesses have now been exposed in order to further develop this simulator for industry use.
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