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Cluster Observations and Theoretical Explanations of Broadband Waves in the Auroral RegionBackrud, Marie January 2005 (has links)
Broadband extremely low-frequency wave emissions below the ion plasma frequency have been observed by a number of spacecraft and rockets on auroral field lines. The importance of these broadband emissions for transverse ion heating and electron acceleration in the auroral regions is now reasonably well established. However, the exact mechanism(s) for mediating this energy transfer and the wave mode(s) involved are not well known. In this thesis we focus on the identification of broadband waves by different methods. Two wave analysis methods, involving different approximations and assumptions, give consistent results concerning the wave mode identification. We find that much of the broadband emissions can be identified as a mixture of ion acoustic, electrostatic ion cyclotron and, ion Bernstein waves, which all can be described as different parts of the same dispersion surface in the linear theory of waves in homogeneous plasma. A new result is that ion acoustic waves occur on auroral magnetic field lines. These are found in relatively small regions interpreted as acceleration regions without cold (tens of eV) electrons. From interferometry we also determine the phase velocity and k vector for parallel and oblique ion acoustic waves. The retrieved characteristic phase velocity is of the order of the ion acoustic speed and larger than the thermal velocity of the protons. The typical wavelength is around the proton gyro radius and always larger than the Debye length which is consistent with ion acoustic waves. We have observed quasi-static parallel electric fields associated with the ion acoustic waves in regions with large-scale currents. Waves, in particular ion acoustic waves, can create an anomalous resistivity due to wave-particle interaction when electrons are retarded or trapped by the electric wave-field. To maintain the large-scale current, a parallel electric field is set up, which then can accelerate a second electron population to high velocities.
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Process development and characterization of sol-gel lead zirconate titanate films for fabrication of flexural plate wave devicesSekhar, Praveen Kumar 01 January 2005 (has links)
In recent years, research on development of chemical, biological and hazardous gas sensors for homeland security have attracted great deal of interest. Actuators possessing high sensitivity, easy fabrication techniques and excellent integration compatibility are in great demand. Towards this need, the development and characterization of improved sol-gel processing for in-house fabrication of highly sensitive and reliable Flexural Plate Wave (FPW) device was pursued This work focuses on an experimental design approach to improve texture and morphology of PZT thin film by systematically controlling the spin, pyrolysis and anneal cycles. The process alterations resulted in an 8-fold increase in the relative intensity of perovskite (111) phase, which consequently yielded a two fold improvement in remnant polarization and coercive field compared to industry recommended processes.
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Resonant ion heating in a helicon plasmaKline, John L. January 1900 (has links)
Thesis (M.S.)--West Virginia University, 1998. / Title from document title page. "Fall 1998." Document formatted into pages; contains iii, 28 p. : ill. (some col.). Includes abstract. Includes bibliographical references (p. 27-28).
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Circuit quantum acoustodynamics with surface acoustic wavesManenti, Riccardo January 2017 (has links)
A highly successful architecture for the exchange of single quanta between coupled quantum systems is circuit quantum electrodynamics (QED), in which the electrical interaction between a qubit and a high-quality microwave resonator offers the possibility to reliably control, store, and read out quantum bits of information on a chip. This architecture has also been implemented with mechanical resonators, showing that a vibrational mode can in principle be manipulated via a coupled qubit. The work presented in this thesis consists of realising an acoustic version of circuit QED that we call circuit quantum acoustodynamics (QAD), in which a superconducting qubit is piezoelectrically coupled to an acoustic cavity based on surface acoustic waves (SAWs). Designing and building this novel platform involved the following main accomplishments: a systematic characterisation of SAW resonators at low temperatures; successfully developing a recipe for the fabrication of Josephson junction on quartz and diamond; measuring the coherence time of superconducting 3D transmon qubits on these substrates and demonstrating the dispersive coupling between a SAW cavity and a qubit on a planar geometry. This thesis presents evidence of the coherent interaction between a SAW cavity and a superconducting qubit in several ways. First of all, a frequency shift of the mechanical mode as a function of qubit frequency is observed. We also measure the acoustic Stark shift of the qubit due to the population of the SAW cavity. The extracted coupling is in agreement with theoretical expectations. A time delayed acoustic Stark shift serves to further demonstrate that the Stark shifts that we observe are indeed due to the acoustic field of the SAW mode. The dispersive coupling between these two quantum systems offers the possibility to perform qubit spectroscopy using the SAW resonator as readout component, indicating that these acoustic resonators can, in principle, be adopted as an alternative qubit readout scheme in quantum information processors. We finally present preliminary measurements of the direct coupling between a SAW resonator and a transmon on diamond, suggesting that strong coupling can in principle be obtained.
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Réalisation d'une pince acoustofluidique pour la manipulation de bioparticulesToru, Sylvain 23 October 2014 (has links)
Cette thèse s’inscrit dans le contexte du développement des laboratoires sur puce (LOC, « Lab On a Chip », permettant de réaliser plusieurs opérations nécessaires à l’analyse d’un échantillon biologique à l'intérieur d'un seul microsystème. Dans ce type de dispositif, de nombreuses étapes sont nécessaires avant d’arriver au résultat d’une analyse donnée (introduction de l'échantillon, concentration, mélange, purification, séparation, etc.). L’équipe microsystèmes du laboratoire Ampère étudie depuis plusieurs années différentes techniques de manipulation sans contact de particules, pour le tri ou de manipulation de particules individuelles dans les laboratoires sur puce, telles que la diélectrophorèse ou la magnétophorèse. Dans cette thèse, nous nous intéressons à la manipulation acoustique de micro particules. Cette technique se révèle notamment avantageuse pour la manipulation d’objets biologiques comme des bactéries, car elle permet de s’affranchir de certaines contraintes de marquage ou de changement de milieu. Notre choix s’est porté sur l’emploi des ondes acoustiques de surface (SAW, « Surface Acoustic Waves »), compatibles avec la filière PDMS très utilisée dans la communauté des LOC. Outre la possibilité de simplifier l’intégration microfluidique de la pince acoustique, la technologie SAW offre une alternative aux dispositifs à pièges acoustiques fixes existant dans la littérature en permettant un contrôle en temps réel des particules piégées. C’est ce que nous avons réalisé expérimentalement : en jouant sur le déphasage entre les signaux d’alimentation électriques des transducteurs électromécaniques, nous pouvons modifier la position des noeuds et des ventres de l’onde acoustique résultante. Ainsi, nous avons pu contrôler en temps réel la position d’une bille en latex de 3 μm ou encore d’un faisceau de bactéries E.coli. Par ailleurs, nous avons réalisé une simulation par éléments finis de la puce acoustofluidique dans son ensemble permettant une meilleure compréhension de tous les phénomènes en jeu et l’optimisation du transfert énergétique entre la source électrique et la particule manipulée. Cette simulation nous indique notamment que l’amplitude de l’onde acoustique stationnaire sur le substrat piézoélectrique varie environ d’un facteur deux en fonction du déphasage imposé entre les deux sources électriques. Cela impacte donc dans la même proportion la force acoustique résultante. Cette variation semble être validée par nos dernières expériences. / In lab-on-a-chip (LOC) technologies, many sample preparation steps are required before achieving a biological analysis on a single chip (sample introduction, concentration, mixing, purification, separation, etc.). The microsystem team of the Ampere Lab has studied for many years different contactless particle manipulation techniques, for sorting or manipulating bioparticles in LOC platforms, such as dielectrophoresis and magnetophoresis. In this thesis, we focus on acoustic manipulation of microparticles. This technique is advantageous for the manipulation of biological objects such as bacteria, because labelling and medium exchange can be avoided. We chose to work with surface acoustic waves (SAW), because this approach is consistent with the use of PDMS, widely used in microfluidics. Besides an easier microfluidic integration of the acoustic tweezers, the SAW technology provides an alternative to the existing devices with fixed acoustic traps, allowing a real time control of the trapped particles. This was experimentally achieved by playing on the phase shift between the two electrical signals driving the IDT, thereby modifying the position of nodes and antinodes of the resulting pressure wave. As a result, we could control in real time the position of a 3 μm latex bead or an E.coli bacteria alignment. We have also developed a finite-element model of the whole acoustofluidic chip allowing a better understanding of the physics and the optimization of the energy transfer between the electrical source and the trapped particle. Among different results, this model informs us that the magnitude of the acoustic radiation force varies by a factor of two with the phase shift between the electrical sources. This result seems to be validated by our last experiments.
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Biofilm Removal Using Bubbles and SoundParini, Michael R. 15 July 2005 (has links) (PDF)
Bacteria in biofilms adhere well to surfaces and are quite difficult to remove. Oral plaque is one example of a biofilm. Many researchers have studied ways to remove plaque and bacteria from surfaces. It has been found that the passage of a bubble across a surface to which bacteria has adhered can remove the bacteria from the surface. Biofilms of Streptococcus mutans were grown on glass coverslips as a simple model for oral plaque. The coverslips were mounted in a Plexiglas chamber filled with artificial saliva. A bubble stream was directed at the mounted biofilm. The velocity, gas fraction, median bubble diameter, and impingement angle were all varied to determine the effect of each parameter on removal and which parameter was the most significant. To investigate the influence of sound on removal, a Ling oscillator was attached to the chamber, and was used simultaneously with and without a bubble stream. The acoustic intensity and the frequency were varied to determine if there was any effect on biofilm removal. Biofilm removal was also video taped. The results of these experiments confirmed that biofilms are removed by a stream of bubbles. Removal of biofilm is a function of stream velocity, gas fraction, and median bubble diameter, but not of impingement angle. The results of the acoustic experiments show that sound does not affect the removal of biofilm under the conditions used in these experiments. Mathematical models relating the removal of biofilm as a function of time were also developed from the data obtained from the video recording of the experiments. Additional tests using acoustic waves to remove biofilm should be performed to determine if more intense sound can remove biofilm. The intensity of the sound used in these experiments was low and the time of exposure was only 5 sec. Additional tests that more closely simulate the conditions of the mouth during brushing, like adding a surfactant, would also provide more insight as to whether bubbles in a clinical setting would remove biofilm.
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Experimental Investigation of the Effects of Acoustic Waves on Natural Convection Heat Transfer from a Horizontal Cylinder in AirProdanov, Katherina V 01 March 2021 (has links) (PDF)
Heat transfer is a critical part of engineering design, from the cooling of rocket engines to the thermal management of the increasingly dense packaging of electronic circuits. Even for the most fundamental modes of heat transfer, a topic of research is devoted to finding novel ways to improve it. In recent decades, investigators experimented with the idea of exposing systems to acoustic waves with the hope of enhancing thermal transfer at the surface of a body. Ultrasound has been applied with some success to systems undergoing nucleate boiling and in single-phase forced and free convection heat transfer in water. However, little research has been done into the use of sound waves to improve heat transfer in air.
In this thesis the impact of acoustic waves on natural convection heat transfer from a horizontal cylinder in air is explored. An experimental apparatus was constructed to measure natural convection from a heated horizontal cylinder. Verification tests were conducted to confirm that the heat transfer could be described using traditional free convection heat transfer theory. The design and verification testing of the apparatus is presented in this work. Using the apparatus, experiments were conducted to identify if the addition of acoustic waves affected the heat transfer. For the first set of experiments, a 40 kHz standing wave was created along the length of the heated horizontal cylinder. While our expectation was that our results would mirror those found in the literature related to cooling enhancement using ultrasound in water (cited in the body of this thesis), they did not. When a 40 kHz signal was used to actuate the air surrounding the heated cylinder assembly, no measurable enhancement of heat transfer was detected. Experiments were also performed in the audible range using a loudspeaker at 200 Hz, 300 Hz, 400 Hz, 500 Hz, and 2,000 Hz. Interestingly, we found that a 200 Hz acoustic wave causes a significant, measurable impact on natural convection heat transfer in air from a horizontal cylinder. The steady-state surface temperature of the cylinder dropped by approximately 12℃ when a 200 Hz wave was applied to the system.
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From Chip to Demonstrator – Biological Sample Separation Using Surface Acoustic Wave-Based MicrofluidicsColditz, Melanie 11 July 2024 (has links)
Medicine is constantly developing and in order to (early) diagnose common diseases, such as cancer, Parkinson's or Alzheimer's, a liquid biopsy-based approach is of increasing relevance. Samples are complex body fluids, especially blood, whereby a separation of the cells, particles and molecules of interest is often necessary for a subsequent analysis. Conventional methods such as centrifugation, the gold standard of many sample preparations, are reaching their limits in terms of gentle cell separation, purity and automatability. At the same time, the volumes of biological samples required for analysis are decreasing and point-of-care solutions are becoming increasingly important. New technologies for sample preparation are therefore urgently needed to meet this demand. Surface acoustic wave (SAW)-based microfluidic systems have already shown promising results in the handling of biological samples, but there is still a lack in the ability to transfer laboratory set-ups into a real-world environment.
In this work, an industrially feasible manufacturing technology for SAW-based microfluidic chips that can be used for separation of blood plasma was developed. For this purpose, polymeric microchannels were integrated directly on the piezoelectric substrate together with the interdigital transducers required for SAW excitation. This was done reproducibly on the wafer-level with established lithographic methods, but a relatively young material system, i.e. dry film resists, allowing an industrial scale-up of the acoustofluidic chips. Furthermore, the chip layout was designed robustly to ensure a stable and continuous separation process and the “lab-around-the-chip” was further developed into an easy-to-use system. Moreover, blood plasma separation at high flow rates of up to 50 μL/min for a 1:5 diluted sample and a throughput of 888,000 cells/s in the SAW-based microfluidic chip was demonstrated. In comparison to microfluidic alternatives, high cell separation purity was achieved with special focus on the use of analytical methods for the detection of low cell concentrations in blood plasma. Direct comparison to centrifugation further indicated a gentler separation method for the cells and more reproducible results. The SAW-based microfluidic system developed in this work offers great potential for future application in liquid biopsy.
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Effects of Discharge Tube Geometry on Plasma Ion OscillationsSimmons, David Warren 05 1900 (has links)
This study considers the effect, on plasma ion oscillations, of various lengths of discharge tubes as well as various cross sections of discharge tubes. Four different gases were used in generating the plasma. Gas pressure and discharge voltage and current were varied to obtain a large number of signals.
A historical survey is given to familiarize the reader with the field. The experimental equipment and procedure used in obtaining data is given. An analysis of the data obtained is presented along with possible explanations for the observed phenomena. Suggestions for future study are made.
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Dispositivos semicondutores a partir de óxidos de estanho e zinco / Tin and zinc oxides semiconductor devicesBatista, Pablo Diniz 13 February 2009 (has links)
Este trabalho apresenta o desenvolvimento de dispositivos semicondutores utilizando óxidos de zinco e estanho. O primeiro dispositivo semicondutor estudado está relacionado ao desenvolvimento de sensores de pH a partir do efeito de campo, enquanto que o segundo consiste na utilização de ondas acústicas de superfície para o transporte de portadores voltados para o desenvolvimento de detectores de um único fóton. Primeiramente, esses materiais foram utilizados como membranas sensíveis a íons de hidrogênio. Para isso foram fabricados os dispositivos denominados EGFETs cujo princípio de funcionamento é semelhante ao ISFET. Foram desenvolvidos filmes de SnO2 obtidos a partir da rota Pechini e pela técncia Sol-gel com o objetivo de investigar a resposta elétrica do EGFET em função da concentração de íons de H+ . Os sensores fabricados pela técnica sol-gel não apresentaram respostas satisfatórias devido à presença de poros. Por outro lado, obtivemos uma sensibilidade de 33mV/pH para o EGFET desenvolvido a partir da rota Pechini com uma membrana calcinada à 400o C. Propusemos também a utilização do ZnO como um possível candidato a sensor de pH a partir do EGFET. A melhor resposta do EGFET (uma sensibilidade de 38mV/pH) foi alcançada com a utilização de filmes de ZnO aquecidos à temperatura de 150o C. Além dos dispositivos para a detecção de íons de H+ apresentamos uma nova abordagem para a detecção de um único fóton a partir da combinação de dispositivos utilizando ondas acústicas de superfície e os transistores de um único elétron. Basicamente os protótipos consistem em uma estrutura de várias camadas otimizadas para uma eficiente absorção de fótons, uma junção p-i-n utilizada para coleta de portadores, IDT para geração da SAW e guias metálicos para controle de portadores durante o transporte acústico. Os portadores são eficientemente transportados por uma distância de 100 mm com uma perda de 12 % para a melhor configuração. Nessas condições, a eficiência do dispositivo é de 75%. / This work presents the study and development of semiconductor devices base on tin and zinc oxides. The first device is related to the development of pH sensors based on field effect, while the second device uses surface acoustic waves for the transport of carriers related to a single photon detector device. Initially, the semiconductors were used as hydrogen ions sensing membranes. For that aim extended gate field effect transistors (EGFET) were developed. Their working principle is similar to the ion sensitive field effect transistor (ISFET). Through Pechini and sol-gel SnO2 thin films were obtained. The EGFET response to H+ ions was not optimal due to the presence of pores. Using Pechini, a response of 33mV/pH was obtained for the EGFET membrane calcinated at 400o C. The use of ZnO as sensing membrane was also investigated, and the best response was a sensibility of 38mV/pH) for a film heated up to 150o C. In addition to the EGFET structure, a new approach to a single photon detection is presented. This uses the combination of surface acoustic waves with a single electron transistor. Two prototypes were developed using a multi-layered structure optimized for photon absorption. Carriers are collected using a p-i-n structure. Inter-digital-transducers are used for surface acoustinc wave generation. Metallic guides are used to control the carriers during acoustic tranport. Carriers were efficiently transported over a length of 100 mm with a loss of 12 % for the best configuration. Under this optimized conditions, the efficiency of the device is 75%.
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