Global ETD Search

11	Advanced test mass suspensions and electrostatic control for AIGO Lee, Benjamin H January 2007 (has links) This thesis presents the research done towards the development of the final mirror suspension stage for the high power test facility at AIGO, Western Australia. One of the goals of the facility is to test advanced suspension methods that may be useful in future gravitational wave detectors. An in depth study of current mirror suspension techniques is presented and areas of possible improvement are highlighted. The extension of an existing suspension modelling toolkit written in Mathematica is also presented, where added functions allow one to include the violin modes of a suspension into their analysis. Through this tool, new suspension geometries boasting a lower number of violin modes with lower Q factors where developed. The orthogonal ribbon suspension and the thin tube suspension boast a lower number of lower Q violin modes compared to typical ribbon suspensions. For the latter, a reduction in the number of violin modes below 5kHz down to 5 and peak thermal noise amplitude by approximately 30dB is predicted. Presented also is the affect that such suspension geometries have on pendulum mode dilution factor and overall suspension thermal noise. It is seen that the violin mode improvement comes at a cost of a small increase in thermal noise above approximately 50Hz. A theoretical analysis of the AIGO cavity locking control scheme is also given. Issues of sensor noise and dynamic range are considered to produce a possible hierarchical locking method that would be compatible with advanced detectors. The resulting actuator force range requirements for AIGO at each actuation location on the vibration isolation system are given. Requirements of local controls before achieving cavity lock are also discussed. Finally, the suspension of a dummy sapphire mirror using removable modular niobium ribbons is presented. The design and performance of an electrostatic actuator and sensor for suspended mirror control is given. Initial experimental results of positioning and control of the final stage suspension through a digital interface is also included. Astronomical observatories -- Australia Electrostatics Gravitational waves Gravity stations -- Australia Interferometers Vibration -- Measurement Gravitational wave detection Electrostatic control Thermal noise
12	Estudo e simulação de ruído em circuitos e dispositivos MOS Della Giustina, Rafael Varela January 2012 (has links) A redução das dimensões dos dispositivos semicondutores para escalas submicrométricas impõe diversos desafios no projeto de circuitos integrados. O impacto das variações intrínsecas afetando parâmetros elétricos cresce em importância à medida que a área dos dispositivos adentra a faixa nanométrica. Dentre essas variações estão flutuações nas tensões e correntes de terminal causadas pelas diferentes formas de ruído intrínseco dos dispositivos MOS. Este trabalho apresenta um estudo sobre o impacto do ruído elétrico no desempenho de circuitos MOS. Um novo modelo para simulação do Random Telegraph Signal (RTS) no domínio do tempo é utilizado. Uma metodologia de simulação para contabilizar o ruído térmico em simulações transientes também é proposta. A partir desses modelos de simulação de dispositivos, o trabalho de pesquisa analisa o impacto da variabilidade de parâmetros elétricos em nível de circuito. As simulações focam na caracterização da pureza espectral em osciladores em anel de sinal diferencial. Diversas topologias são apresentadas e posteriormente comparadas em termos do jitter no período de oscilação. / The shrinking of semiconductors devices dimensions to submicron scales introduces many challenges in integrated circuit design. The impact of intrinsic variability affecting electrical parameters increases in importance as transistors enter the nanometric range. Among these variations are fluctuations in terminal voltages and currents caused by different forms of intrinsic noise of MOS devices A new model for Random Telegraph Signal (RTS) simulation in time-domain is utilized. A simulation methodology to account for thermal noise effects in transient simulations is also proposed. Using these simulation models, this research work analyses the impact of electrical noise at circuit level. The simulations focus on the characterization of spectral purity in differential ring oscillators. Different topologies are presented and compared in terms of jitter in the period of oscillation. Microeletrônica Circuitos integrados Simulação numérica Ruído Electrical engineering Microelectronics Low-frequency noise Thermal noise Reliability of integrated circuits
13	Estudo e simulação de ruído em circuitos e dispositivos MOS Della Giustina, Rafael Varela January 2012 (has links) A redução das dimensões dos dispositivos semicondutores para escalas submicrométricas impõe diversos desafios no projeto de circuitos integrados. O impacto das variações intrínsecas afetando parâmetros elétricos cresce em importância à medida que a área dos dispositivos adentra a faixa nanométrica. Dentre essas variações estão flutuações nas tensões e correntes de terminal causadas pelas diferentes formas de ruído intrínseco dos dispositivos MOS. Este trabalho apresenta um estudo sobre o impacto do ruído elétrico no desempenho de circuitos MOS. Um novo modelo para simulação do Random Telegraph Signal (RTS) no domínio do tempo é utilizado. Uma metodologia de simulação para contabilizar o ruído térmico em simulações transientes também é proposta. A partir desses modelos de simulação de dispositivos, o trabalho de pesquisa analisa o impacto da variabilidade de parâmetros elétricos em nível de circuito. As simulações focam na caracterização da pureza espectral em osciladores em anel de sinal diferencial. Diversas topologias são apresentadas e posteriormente comparadas em termos do jitter no período de oscilação. / The shrinking of semiconductors devices dimensions to submicron scales introduces many challenges in integrated circuit design. The impact of intrinsic variability affecting electrical parameters increases in importance as transistors enter the nanometric range. Among these variations are fluctuations in terminal voltages and currents caused by different forms of intrinsic noise of MOS devices A new model for Random Telegraph Signal (RTS) simulation in time-domain is utilized. A simulation methodology to account for thermal noise effects in transient simulations is also proposed. Using these simulation models, this research work analyses the impact of electrical noise at circuit level. The simulations focus on the characterization of spectral purity in differential ring oscillators. Different topologies are presented and compared in terms of jitter in the period of oscillation. Microeletrônica Circuitos integrados Simulação numérica Ruído Electrical engineering Microelectronics Low-frequency noise Thermal noise Reliability of integrated circuits
14	Estudo e simulação de ruído em circuitos e dispositivos MOS Della Giustina, Rafael Varela January 2012 (has links) A redução das dimensões dos dispositivos semicondutores para escalas submicrométricas impõe diversos desafios no projeto de circuitos integrados. O impacto das variações intrínsecas afetando parâmetros elétricos cresce em importância à medida que a área dos dispositivos adentra a faixa nanométrica. Dentre essas variações estão flutuações nas tensões e correntes de terminal causadas pelas diferentes formas de ruído intrínseco dos dispositivos MOS. Este trabalho apresenta um estudo sobre o impacto do ruído elétrico no desempenho de circuitos MOS. Um novo modelo para simulação do Random Telegraph Signal (RTS) no domínio do tempo é utilizado. Uma metodologia de simulação para contabilizar o ruído térmico em simulações transientes também é proposta. A partir desses modelos de simulação de dispositivos, o trabalho de pesquisa analisa o impacto da variabilidade de parâmetros elétricos em nível de circuito. As simulações focam na caracterização da pureza espectral em osciladores em anel de sinal diferencial. Diversas topologias são apresentadas e posteriormente comparadas em termos do jitter no período de oscilação. / The shrinking of semiconductors devices dimensions to submicron scales introduces many challenges in integrated circuit design. The impact of intrinsic variability affecting electrical parameters increases in importance as transistors enter the nanometric range. Among these variations are fluctuations in terminal voltages and currents caused by different forms of intrinsic noise of MOS devices A new model for Random Telegraph Signal (RTS) simulation in time-domain is utilized. A simulation methodology to account for thermal noise effects in transient simulations is also proposed. Using these simulation models, this research work analyses the impact of electrical noise at circuit level. The simulations focus on the characterization of spectral purity in differential ring oscillators. Different topologies are presented and compared in terms of jitter in the period of oscillation. Microeletrônica Circuitos integrados Simulação numérica Ruído Electrical engineering Microelectronics Low-frequency noise Thermal noise Reliability of integrated circuits
15	Noise sources in the electric field antenna on the ESA JUICE satellite Odelstad, Elias January 2013 (has links) The noise in the Langmuir Probe and Plasma Wave Instrument (LP-PWI) on board ESA:s future Jupiter satellite JUICE (Jupiter ICy Moons Explorer) was investigated. Thermal Johnson-Nyquist noise and shot noise, caused by fluctuations in the probe-plasma currents, were combined with the quasi-thermal noise (QTN) due to thermal fluctuations in the electric field in the plasma, using a small signal equivalent circuit model. The contributions and effects of each of the considered noise sources were examined and compared for a number of representative space plasma conditions, including the cold dense plasma of Ganymede's ionosphere and the hot tenuous plasma out in the Jovian magnetosphere. The results showed that in the cold dense plasma of Ganymede's ionosphere, the antenna was long compared to the Debye length and the quasi-thermal noise had a clearly pronounced peak and a steep high-frequency cut-off. For an antenna biased to 1 V with respect to the plasma, the shot noise due to the ambient plasma was the dominant source of noise. For a an antenna at the floating potential the photoelectron shot noise coalesced with the shot and Nyquist noises of the ambient plasma to form almost a single curve. In the hot tenuous plasma out in Jupiter's magnetosphere, the antenna was short compared to the Debye length and the QTN spectrum was much flatter, with little or no peak at the plasma frequency and a very weak high-frequency cut-off. For an antenna biased to 1 V, the shot noise due to photoelectron emission dominated at Callisto's orbital position whereas at Ganymede's and Europa's orbital positions the Nyquist and shot noises of the ambient plasma particles were the dominant noise components. For an antenna at the floating potential, the shot and Nyquist noises of the ambient plasma also dominated the output noise, except at Europa's orbital position, where the quasi-thermal noise was the largest noise component for frequencies at and above the plasma frequency. The numerical calculations were performed using MATLAB. The code was made available in a Git repository at https://github.com/eliasodelstad/irfuproj_JUICE_noise. JUICE noise quasi-thermal noise QTN Nyquist noise shot noise Langmuir probes electric field probes Engineering and Technology Teknik och teknologier
16	Nanotubes de carbone comme sondes en microscopie à force atomique : nanomécanique et étude à l’interface air-liquide de fluides complexes Buchoux, Julien 28 January 2011 (has links) La microscopie à force atomique exploite les interactions entre une sonde et un échantillon. Les nanotubes de carbone représentent la sonde idéale, ils sont: fins, robustes, peu réactifs et ont un haut rapport d'aspect. L'utilisation à grande échelle des sondes à nanotubes de carbone passe par l'étude de leur comportement mécanique en contact avec une surface. Nous étudions deux types de sondes: les sondes avec nanotubes multiparois et les sondes avec nanotubes monoparois. Pour les nanotubes multiparois nous avons utilisé trois mode de fonctionnement AFM différents que sont les modes contact, modulation de fréquence et bruit thermique. Les résultats expérimentaux sont comparés à des modèles mécaniques que nous avons développés. Les études des nanotubes monoparois ont été réalisées à partir d'un AFM interférométrique. Ces mesures nous ont permis de déterminer l'énergie d'adhésion par unité de longueur d'un nanotube monoparoi sur des surfaces de graphite et mica.Enfin nous présentons deux applications des sondes AFM avec nanotube multiparoi. La première est un projet de sondes électrochimiques pour lesquelles un nanotube multiparoi sert de nanolocalisateur. La seconde est une étude par AFM d'une interface air-liquide de fluides complexes. / Atomic force microscopy exploits interactions between a probe and a sample. Carbon nanotubes represent the ideal probe; they are thin with a high aspect ratio, robustes and few reactive. The widespread use of carbon nanotube probes needs the study of their mechanical behavior in contact with a surface. We study two types of probes: probes with multiwalled nanotubes and probes with singlewalled nanotubes. For multiwalled nanotubes, we used three differents AFM modes that are contact, frequency modulation and thermalnoise. The experimental results are compared with mechanical models that we developed. Studies of singlewalled nanotubes have been produced from an interferometric AFM. These measures have enabled us to determine the adhesion energy per unit length of singlewalled nanotubes on graphite and mica surfaces.Finally we present two applications of AFM probes with multiwall nanotubes. The first is a project of electrochemical sensors for which a multiwall nanotube is used as a nanolocalisator. The second is a study by AFM of air-liquid interface of complex fluids. Afm Nanotube de carbone Multiparoi Monoparoi Bruit thermique Mode contact Modulation de fréquence Nanomécanique Afm Carbon nanotube Multiwalled Singlewalled Thermal noise Contact mode Frequency modulation Nanomechanics
17	Quantum transport investigations of low-dimensional electron gases in AlxGa1-xAs/GaAs- and Bi2Se3-based materials Riha, Christian 30 August 2019 (has links) Die Transporteigenschaften eines Elektronengases mit reduzierter Dimensionalität werden von den Welleneigenschaften der Elektronen bestimmt. Dies ermöglicht es, verschiedene Quanteneffekte, wie Quanteninterferenz, zu beobachten. Im ersten Teil dieser Arbeit werden geätzte Quantenringe und eindimensionale (1D) Verengungen, basierend auf AlxGa1-xAs/GaAs-Heterostrukturen, hinsichtlich ihrer Transporteigenschaften untersucht. Messungen des thermischen Rauschens im Gleichgewichtszustand zeigen, dass der Erwartungswert mit den Rauschspektren aller 1D Verengungen übereinstimmt, jedoch um bis zu 60 % bei allen Quantenringen überschritten wird. Rauschmessungen im thermischen Nichtgleichgewicht ergeben, dass der Wärmefluss in Quantenringen mithilfe einer globalen Steuerelektrode (Topgate) an- und ausgeschaltet werden kann. Die magnetische Widerstandsänderung der Quantenringe zeigt Oszillationen, die dem Aharonov-Bohm-Effekt zugeordnet werden. Die Beobachtbarkeit dieser Oszillationen hängt stark von dem Abkühlvorgang der Probe ab und die Oszillationen zeigen Hinweise auf ein Schwebungsmuster sowie auf Phasenstarre. Im zweiten Teil der Arbeit werden die Oberflächenzustände von exfolierten Bi2Se3 Mikroflocken untersucht. Für Mikroflocken mit metallischen Temperaturabhängigkeiten des Widerstandes wurde schwache Anti-Lokalisierung beobachtet. Diese Beobachtung deutet darauf hin, dass sich die magnetische Widerstandsänderung weniger ausschließlich aus den 2D Oberflächenkanälen als vielmehr aus einem geschichtetem Transport von 2D Kanälen im Volumenkörper zusammensetzt. Eine Mikroflocke mit halbleitenden Eigenschaften zeigt keine Hinweise auf solch einen geschichteten 2D Transport und es wird angenommen, dass ihre magnetische Widerstandsänderung ausschließlich von den 2D Oberflächenzuständen verursacht wird. / The transport properties of an electron gas with reduced dimensionality are dominated by the electron’s wave nature. This allows to observe various quantum effects, such as quantum interference. In the first part of this thesis etched quantum rings and one-dimensional (1D) constrictions, based on AlxGa1-xAs/GaAs heterostructures, are investigated with respect to their transport properties. Thermal noise measurements in equilibrium show that the expectation value agrees with the noise spectra of all 1D constrictions but is exceeded by up to 60 % for the noise spectra of all quantum rings. Noise measurements in thermal non-equilibrium reveal that the heat flow can be switched on and off for a quantum ring by a global top-gate. The measured magnetoresistance of the quantum rings shows oscillations that are attributed to the Aharonov-Bohm effect. The observability of these oscillations strongly depends on the cooling process of the sample and the oscillations show indications of a beating as well as phase rigidity. In the second part of the thesis the surface states of exfoliated Bi2Se3 microflakes are studied. For microflakes that show a metallic temperature dependence of the resistance weak anti-localization is observed. This observation suggests that the magnetoresistance is a result of layered transport of 2D channels in the bulk rather than just the surface 2D channels. A microflake with semiconducting characteristics does not show indications of such a 2D layered transport and its magnetoresistance is considered to be carried by the 2D surface states only. Thermisches Rauschen Niederdimensionaler Elektronentransport Quanteninterferenz Topologische Isolatoren Thermal noise Low-dimensional electron transport Quantum interference Topological insulators 530 Physik UP 3150 UP 5050 ddc:530
18	Understanding the Relationship Between Thermal and Photochemical Isomerization in Visual Receptors Gozem, Samer 24 July 2013 (has links) No description available. Biochemistry Physical Chemistry Chemistry Rhodopsin thermal isomerization QM-MM conical intersection computational chemistry visual pigments thermal noise photochemistry photobiology quantum biology transition state dynamic electron correlation retinal photoreceptors
19	Imagerie computationnelle active et passive à l’aide d’une cavité chaotique micro-ondes / Active and passive computational imaging using a microwave chaotic cavity Tondo Yoya, Ariel Christopher 12 December 2018 (has links) Les travaux présentés dans cette thèse portent sur l’imagerie computationnelle active et passive en micro-ondes. L’utilisation d’une cavité chaotique comme composants compressif est étudiée tant théoriquement (modèle mathématique, résolution algorithmique du problème inverse) et expérimentalement. L’idée sous-jacente est de remplacer un réseau d’antennes par une unique cavité réverbérante dont un réseau d’ouvertures sur la face avant permet de coder l’information spatiale d’une scène dans la réponse temporelle de la cavité. La réverbération des ondes électromagnétique à l’intérieur de la cavité fournit les degrés de liberté nécessaires à la reconstruction d’une image de la scène. Ainsi il est possible de réaliser en temps réel une image haute-résolution d’une scène à partir d’une unique réponse impulsionnelle. Les applications concernent la sécurité ou l’imagerie à travers les murs. Dans ce travail, la conception et la caractérisation d’une cavité chaotique ouverte sont effectuées. L’utilisation de ce dispositif pour réaliser en actif des images de cibles de diverses formes est démontrée. Le nombre de degrés de liberté est ensuite amélioré en modifiant les conditions aux limites grâce à l’ajout lampes fluorescentes. L’interaction des ondes avec ces éléments plasma permet de créer de nouvelles configurations de la cavité, améliorant ainsi la résolution des images. L’imagerie compressive est ensuite appliquée à la détection et localisation passive du rayonnement thermique naturel de sources de bruit, à partir de la corrélation des signaux reçus sur deux voies. Enfin, une méthode novatrice d’imagerie interférométrique de cibles est présentée. Elle est basée sur la reconstruction de la réponse impulsionnelle entre deux antennes à partir du bruit thermique micro-ondes émis par un réseau de néons. Ces travaux constituent une avancée vers les systèmes d’imagerie futurs. / The broad topic of the presented Ph.D focuses on active and passive microwave computational imaging. The use of a chaotic cavity as a compressive component is studied both theoretically (mathematical model, algorithmic resolution of the inverse problem) and experimentally. The underlying idea is to replace an array of antennas with a single reverberant cavity with an array of openings on the front panel that encodes the spatial information of a scene in the temporal response of the cavity. The reverberation of electromagnetic waves inside the cavity provides the degrees of freedom necessary to reconstruct an image of the scene. Thus it is possible to create a high-resolution image of a scene in real time from a single impulse response. Applications include security or imaging through walls. In this work, the design and characterization of an open chaotic cavity is performed. Using this device, active computational imaging is demonstrated to produce images of targets of various shapes. The number of degrees of freedom is further improved by changing the boundary conditions with the addition of commercial fluorescent lamps. The interaction of the waves with these plasma elements allows new cavity configurations to be created, thus improving image resolution. Compressive imaging is next applied to the passive detection and localization of natural thermal radiation from noise sources, based on the correlation of signals received over two channels. Finally, an innovative method of interferometric target imaging is presented. It is based on the reconstruction of the impulse response between two antennas from the microwave thermal noise emitted by a network of neon lamps. This work constitutes a step towards for future imaging systems. Cavité chaotique Degré de liberté Imagerie passive Corrélation Speckle Matrice aléatoire Bruit thermique Émissivité Problème inverse Chaotic cavity Degree of freedom Passive imaging Correlation Speckle Random matrix Thermal noise Emissivity Reverse problem
20	Exploring nano-mechanics through thermal fluctuations Bellon, Ludovic 23 November 2010 (has links) (PDF) This mémoire presents my current research interests in micro and nano-mechanics in a comprehensive manuscript. Our experimental device is first presented: this atomic force microscope, designed and realized in the Laboratoire de Physique de l'ENS Lyon, is based on a quadrature phase differential interferometer. It features a very high resolution (down to 10 fm/rtHz) in the measurement of deflexion, down to low frequencies and on a huge input range. The dual output of the interferometer implies a specific handling to interface common scanning probe microscope controllers. We developed analog circuitries to tackle static (contact mode) and dynamic (tapping mode) operations, and we demonstrate their performance by imaging a simple calibration sample. As a first application, we used the high sensitivity of our interferometer to study the mechanical behavior of micro-cantilevers from their fluctuations. The keystone of the analysis is the Fluctuation-Dissipation Theorem (FDT), relating the thermal noise spectrum to the dissipative part of the response. We apply this strategy to confront Sader's model for viscous dissipation with measurements on raw silicon cantilevers in air, demonstrating an excellent agreement. When a gold coating is added, the thermal noise is strongly modified, presenting a 1/f like trend at low frequencies: we show that this behavior is due to a viscoelastic damping, and we provide a quantitative phenomenological model. We also characterize the mechanical properties of cantilevers (stiffness and Elastic Moduli) from a mapping of the thermal noise on their surface. This analysis validates the description of the system in term of its normal modes of oscillations in an Euler-Bernoulli framework for flexion and in Saint-Venant approach for torsion, but points toward a refined model for the dispersion relation of torsional modes. Finally, we present peeling experiments on a single wall carbon nanotube attached to the cantilever tip. It is pushed against a flat substrate, and we measure the quasi-static force as well as the dynamic stiffness using an analysis of the thermal noise during this process. The most striking feature of these two observables is a plateau curve for a large range of compression, the values of which are substrate dependent. We use the Elastica to describe the shape of the nanotube, and a simple energy of adhesion per unit length Ea to describe the interaction with the substrate. We analytically derive a complete description of the expected behavior in the limit of long nanotubes. The analysis of the experimental data within this simple framework naturally leads to every quantity of interest in the problem: the force plateau is a direct measurement of the energy of adhesion Ea for each substrate, and we easily determine the mechanical properties of the nanotube itself. [PHYS:PHYS] Physics/Physics thermal noise AFM atomic force microscopy cantilever Sader model interferometry dissipation carbon nanotube high precision metrology FDT Kramers-Kronig Elastica stiffness viscoleasticity coating

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