Global ETD Search

101	Advanced Interferometry for Gravitational Wave Detection Shaddock, Daniel Anthony, Daniel.Shaddock@jpl.nasa.gov January 2001 (has links) In this thesis we investigate advanced techniques for the readout and control of various interferometers. In particular, we present experimental investigations of interferometer configurations and control techniques to be used in second generation interferometric gravitational wave detectors. We also present a new technique, tilt locking, for the readout and control of optical interferometers. ¶ We report the first experimental demonstration of a Sagnac interferometer with resonant sideband extraction (RSE). We measure the frequency response to modulation of the length of the arms and demonstrate an increase in signal bandwidth of by a factor of 6.5 compared to the Sagnac with arm cavities only. We compare Sagnac interferometers based on optical cavities with cavity-based Michelson interferometers and find that the Sagnac configuration has little overall advantage in a cavity-based system. ¶ A system for the control and signal extraction of a power recycled Michelson interferometer with RSE is presented. This control system employs a frontal modulation scheme requiring a phase modulated carrier field and a phase modulated subcarrier field. The system is capable of locking all 5 length degrees of freedom and allows the signal cavity to be detuned over the entire range of possibilities, in principle, whilst maintaining lock. We analytically investigate the modulation/demodulation techniques used to obtain these error signals, presenting an introductory explanation of single sideband modulation/demodulation and double demodulation. ¶ This control system is implemented on a benchtop prototype interferometer. We discuss technical problems associated with production of the input beam modulation components and present several solutions. Operation of the interferometer is demonstrated for a wide range of detunings. The frequency response of the interferometer is measured for various detuned points and we observe good agreement with theoretical predictions. The ability of the control system to maintain lock as the interferometer is detuned is experimentally demonstrated. ¶ Tilt locking, a new technique to obtain an error signal to lock a laser to an optical cavity, is presented. This technique produces an error signal by efficient measurement of the interference between the TEM00 and TEM10 modes. We perform experimental and theoretical comparisons with the widely used Pound-Drever-Hall (PDH) technique. We derive the quantum noise limit to the sensitivity of a measurement of the beam position, and using this result calculate the shot noise limited sensitivity of tilt locking. We show that tilt locking has a quantum efficiency of 80%, compared to 82% for the PDH technique. We present experimental demonstrations of tilt locking in several applications including frequency stabilisation, continuous-wave second harmonic generation, and injection locking of a Nd:YAG slab laser. In each of these cases, we demonstrate that the performance of tilt locking is not the limiting factor of the lock stability, and show that it achieves similar performance to the PDH based system. ¶ Finally, we discuss how tilt locking can be effectively applied to two beam interferometers. We show experimentally how a two beam interferometer typically gives excellent isolation against errors arising from changes in the photodetector position, and experimentally demonstrate the use of tilt locking as a signal readout system for a Sagnac interferometer. interferometry gravitational waves tilt locking injection locking optical cavity resonanant sideband extraction Sagnac interferometer Michelson interferometer power recycling signal recycling spatial mode interference modulation demodulation frequency stabilisation
102	The Double Mach-Zehnder Interferometric Hydrophone Based on a Dual Sagnac Ring Configuration Liu, Shu-Xuan 14 July 2004 (has links) This paper reports a reciprocal Mach-Zehnder interferometer in a dual Sagnac ring configuration, and one of two arms in Mach-Zehnder interferometer is used for underwater optic fiber hydrophone. Two Mach-Zehnder interferometers operated in opposite sense are simultaneously induced from the underwater acoustic wave and the PZT phase modulation. Thus, at the output, four interferometric beams occur such that the intensity of interferometric beams will enhance. In general, one stage of a double Mach-Zehnder interferometer is just used as a sensor, another one for compensation. Specially, this paper presents two stages of a double Mach-Zehnder interferometer sense the measurand at the same time due to the topology structure of Sagnac ring pairs. In the other words, the characteristic is to win the affection of two beauties at the same time. Two rings in the same direction make a Mach-Zehnder interferometer. Besides, the inner ring in the clockwise direction and the outer one in the counterclockwise direction also make a Mach-Zehnder interferometer. So as to the unbalanced arms of the Mach-Zehnder interferometer, the underwater acoustic wave induces the light beam phase difference in optic fiber hydrophone interrogator to demodulate the acoustic wave signal by PGC circuit. phase-generated carrier demodulation Fiber Bragg grating Mach-Zehnder interferometer fiber optic hydrophone dual Sagnac ring interferometer Pb zirconate titanate phase modulator
103	Měření velmi malých výchylek pomocí optovláknového interferometru / Measurement of very small displacements with fiber-optic interferometer Vybíral, Dominik January 2020 (has links) This master's thesis is focused on optical methods of measurement of very small dynamic displacements. Principles of interfermeters with picometer resolution including Fabry-Pérot interferometer are discussed and an integration using this interferometer was designed. Parasitic influencers of Fabry-Pérot interferometer were described as well as signal processing methods for interferometer's output signal. An interferometric meter for measurement of dynamic displacement was designed with frequency range of several kHz. These parameters are achieved under condition of photonic crystal layer placed on measured sample.
104	Undisturbed interferometric sensing through a fluid interface by electrically-tunable lenses and micro mirrors Czarske, Jürgen, Leithold, C., Radner, Hannes, Büttner, Lars, Stürmer, Moritz, Wallrabe, U. 14 August 2019 (has links) We have harnessed the power of various programmable photonics devices for an interferometric measurement technique. Distortion-free laser-based velocity measurements through a dynamic gas-liquid interface are enabled by a closed-loop optoelectronic system. We are employing electrically tunable lenses and micro mirrors to correct low-order wavefront distortions effectively. Our work represents a paradigm shift in interferometric velocity measurement techniques from using static to dynamic optical elements. info:eu-repo/classification/ddc/620 ddc:620
105	A Platform for a Wheeler's Delayed-Choice Experiment in Optical Fiber / En fiberoptisk plattform till Wheeler's experiment med sent val Åhlgren, Gustaf January 2022 (has links) Quantum mechanics has played a big role in the development of our understanding of the smallest things in the universe. It has provided descriptions for phenomena like single electrons or single photons, which are single particles of light. One of the most mysterious properties of quantum systems is the ability to behave as a particle or a wave. In 1978, J. A. Wheeler devised an experiment to investigate if a quantum system knows in advance if it should propagate as a wave or as a particle through an experiment, by changing the experiment after the quantum system has entered the experimental set-up. Here an optical all-in fiber platform for a Wheeler's delayed choice experiment is modeled, constructed and tested using commercially available fiber optic components. This is in contrast to previous delayed choice experiments, which have used free-space components in some parts of their experimental set-up. The optical set-up was modeled and simulated using a quantum formalism, with future work in mind if the platform is used to perform a quantum delayed-choice experiment. The platform used a Sagnac interferometer as the second beamsplitter in a Mach-Zehnder interferometer, to perform the choice of measuring either particle or wave properties. Using a fiber platform, the length of the platform can easily be extended with more fiber to accommodate a large separation between the beamsplitter in the beginning of the set-up, and the Sagnac interferometer at the end of the set-up. The result was a stable platform to measure particle behavior of light with good performance, and the ability to switch between these measurements on the fly. The system was tested with classical light, but the light source can be changed from a laser, to for example an attenuated laser, to enter the quantum domain for performing a quantum delayed-choice experiment using the platform. / Kvantmekaniken har inneburit stora genombrott i vår förståelse av de allra minsta tingen i universum. Kvantmekaniken har gett oss beskrivningar av fenomen som enstaka elektroners beteende eller enstaka ljuspartiklar, så kallade fotoner. En av de märkligaste egenskaperna som finns hos subatomära partiklar är förmågan att upptärda som en våg eller som en partikel, beroende på sammanhanget. År 1978 beskrev J. A. Wheeler ett experiment för att undersöka om en kvantmekanisk partikel, till exempel en foton, vet i förväg om den skall färdas som en partikel eller som en våg genom en experimentuppställning. Undersökningen av detta görs genom att ändra experimentuppställningen samtidigt som den kvantmekaniska partikeln färdas genom uppställningen. En fiberoptisk plattform för Wheelers experiment med sent val modelleras, byggs med kommersiella fiberoptiska komponenter och testas i denna uppsats. Detta skiljer sig från tidigare experiment som har använt frirymds optik i någon del av experimentuppställningen. Den optiska kretsen modelleras med kvantmekanikens formalism, detta för att underlätta för framtida experiment som använder plattformen för att genomföra den kvantmekaniska varianten av Wheelers experiment med sent val. Plattformen består av en Sagnac interferometer som ersätter den andra stråldelaren i en Mach-Zehnder interferometer, och därmed ger funktionen att kunna byta mellan mätning av partikelegenskaper och mätning av vågegenskaper. Den fiberoptiska plattformen är enkel att förlänga för att skapa ett långt avstånd mellan den första stråldelaren och Sagnac interferometern. Resultatet var en stabil plattform med god förmåga att mäta partikelegenskaper respektive vågegenskaper hos ljus och byta mellan dessa mätlägen under experimentets gång. Systemet testades med klassikt laserljus men denna ljuskälla kan enkelt bytas ut mot en dämpad laser för att komma ned på ljusnivåer med enstaka fotoner, och därmed kunna genomföra den kvantmekaniska varianten av Wheelers experiment med sent val. Wheeler's delayed choice wave-particle delayed choice Sagnac interferometer Mach-Zehnder interferometer complementarity relation Atom and Molecular Physics and Optics Atom- och molekylfysik och optik Communication Systems Kommunikationssystem
106	Rare earth technology: magnetic cooling and magnetic separation Lei, Zhe 30 November 2018 (has links) This dissertation deals with two prospectives of rare earth technology. It’s application in magnetic cooling as well as its harvesting and recycling phase. The emphasis is on mapping and manipulating the transport processes of energy and mass, during magnetic cooling and rare earth magnetic separation, under the influence of magnetic field. Distinguished by the driving force of flow field, they belong to the context of magnetohydrodynamics and ferrohydrodynamics, respectively. Multiple aspects are investigated with respect to magnetic cooling. First, the transient dynamics of heat transfer from two periodically magnetized gadolinium (Gd) plates into a heat transfer fluid (n-decane) is studied. It demonstrates that the propagation of the thermal fronts emanating from the Gd plates after magnetization or demagnetization obeys a √t-dependence. A finite time required for magnetization and demagnetization causes a spatially delayed propagation of the thermal fronts. The diffusive heat flux, derived from the temperature profiles, experiences a drop down by about 80% after first 3 seconds while the percentage of thermal energy transferred into n-decane experiences a maximum there. With a stagnant fluid, this work provides reasons for lower bounds of geometry and operation frequency of a simplified parallel-plate structure in the diffusive limit. Furthermore, the potential of magnetohydrodynamic (MHD) convection to increase heat transfer during magnetic cooling is tested. To do this, a section of an active magnetic regenerator is considered, namely a flat gadolinium plate, immersed in an initially stagnant heat transfer fluid (NaOH) which is placed in a cuboid glass cell. To create the MHD flow, a small electric current is injected by means of two electrodes and interacts with the already present magnetic field. As a result, a Lorentz force is generated, which drives a swirling flow in the present model configuration. By means of particle image velocimetry and Mach-Zehnder interferometry, the flow field and its impact on the heat transfer at the gadolinium plate is analyzed. For the magnetization stage, a heat transfer enhancement by about 40 % can be achieved even with low currents of 3 mA is found. In parallel to enhance the heat transfer by an actively stirring of the heat transfer fluid by means of MHD, alternative fluid candidate is also investigated. A room temperature eutectic liquid metal GaInSn, with superior Pr≈ 0.03, and comparable viscosity like that of water is tested in a segment of parallel plate AMR. Due to the high electric conductivity, velocity field of GaInSn contrasting to that of aqueous based ones is strongly influenced by magnetic field due to Lorentz force. Therefore, preliminary velocity measurements by means of ultrasound doppler velocimetry with a quasi homogeneous static magnetic field (220 mT) in a duct channel at the non-conducting Shercliff walls are conducted. The Hartmann walls are constituted of two parallel Gd plates. The second part of this dissertation, rare earth harvesting and recycling, aims to answer the question of why an enrichment of paramagnetic ions can be observed in a magnetic field gradient despite the presence of a counteracting Brownian motion. For that purpose, a rare-earth chloride (DyCl3) solution is studied in which weak evaporation is adjusted by means of small differences in the vapor pressure. The temporal evolution of the refractive index field of this solution, as a result of heat and mass transfer, is measured by means of a Mach–Zehnder interferometer. A numerical algorithm is developed that splits the refractive index field into two parts, one space-dependent and conservative and the other time-dependent and transient. By using this algorithm in conjunction with a numerical simulation of the temperature and concentration field, it is able to show that 90% of the refractive index in the evaporation-driven boundary layer is caused by an increase in the concentration of Dy(III) ions. A simplified analysis of the gravitational and magnetic forces, entering the Rayleigh number, leads to a diagram of the system’s instability. Accordingly, the enrichment layer of elevated Dy(III) concentration is placed in a spatial zone dominated by a field gradient force. This leads to the unconditional stability of this layer in the present configuration. The underlying mechanism is the levitation and reshaping of the evaporation-driven boundary layer by the magnetic field gradient. info:eu-repo/classification/ddc/620 ddc:620
107	Quality assessments of solder bump interconnections in ball grid array packages using laser ultrasonics and laser interferometer Gong, Jie 27 May 2016 (has links) Surface mount devices (SMDs), such as flip chip packages and ball grid array (BGA) packages are gaining in popularity in microelectronics industry because they provide high density inputs/outputs, better electrical and thermal performance. However, these solder bump interconnections in SMDs are sandwiched between the silicon die and the substrate, which makes them challenging to be inspected. Current non-destructive solder bump inspection techniques like electrical testing, X-ray and acoustic microscopy have some application gaps. New solder bump inspection technique is urgently needed to fill these gaps. Previous work has shown the potential of using a non-contact, non-destructive laser ultrasonics and laser interferometer based inspection system for assessing solder bump qualities. The system uses a pulsed Nd:YAG laser to induce ultrasound in the chip packages and a laser interferometer to measure the transient out-of-plane displacement on the package surface. The quality of the solder bumps can be evaluated by analyzing the out-of-plane displacement. However, there are still some gaps that need to be addressed before the system is ready on the shelf. This dissertation focuses on addressing some of these existing issues. The research work consists of the following: 1) a control interface was developed to integrate all the different modules to achieve automation. 2) a new signal-processing method for analyzing the transient out-of-plane displacement signals without requiring a known-good reference chip was developed. 3) the application scope of the system was expanded to inspect the second level solder bumps in BGA packages. Two types of process-induced defects including poor-wetting and solder bump voids were investigated. Meanwhile, solder bump fatigue caused by cyclic mechanical bending and thermal cycle was also studied using this system. 4) a finite element analysis was performed to study the thermo-mechanical reliability of solder bumps in PBGA package under cyclic thermal loads. The successful completion of the research objectives has led to a laser ultrasound solder bump inspection system prototype with more user-friendliness, higher throughputs, better repeatability and more flexibility, which accelerate the commercialization the system. Laser ultrasound Chip package Interferometer Signal processing Solder bump Quality and reliability BGA package Wave propagation
108	Optical properties of semiconductors quantum microcavity structures Afshar, Abolfazl Mozaffari January 1996 (has links) No description available. 539.7
109	Beam splitting mechanisms for a caesium atom interferometer Godun, Rachel M. January 2000 (has links) No description available. 539.7
110	Interferometric filter-based planar Doppler velocimetry Lu, Zenghai January 2008 (has links) This thesis describes the development of a Mach-Zehnder interferometric filter based planar Doppler velocimetry (MZI-PDV) flow measurement technique. The technique uses an entirely new optical system, an unbalanced MZI incorporating glass blocks for wavefront-matching, to replace the iodine cell currently used in conventional PDV. The free spectral range of the interferometric filter can be selected by adjusting the optical path difference of the MZI. This allows the velocity measurement range, sensitivity and resolution to be varied. This system offers no restricts to the choice of laser wavelength of operation which is not the case with most techniques. Two techniques to process the interference fringe images are presented. The first uses the shift of the fringe pattern to determine the Doppler frequency shift along profiles. The second provides a full-field measurement by normalising the received light intensity at each pixel in the image. With the single camera MZI-PDV scheme, exact alignment of the two output images on the active area of the camera is automatic. This eliminates the pixel-matching problem in conventional two camera PDV systems. The technique allows the measurement of up to three components of the flow velocity across a plane defined by a laser light sheet. The construction of a single velocity component MZI-PDV system that incorporates a phase-locking system designed to stabilise the filter is described. Measurements are made on the velocity field of a rotating disc with maximum velocities of ~±70ms-1 and an axis-symmetric air jet (with a nozzle diameter of 20mm) with an exit velocity of ~85ms-1. Standard deviations in the measured velocities were found to be about 2.9 and 2ms-1 for the two processing methods respectively. The system was then modified to make 3-component velocity measurements using imaging fibre bundles to port multiple views to a single detector head, and the standard deviation of the velocity error is around ±3ms-1 for a maximum velocity of ~±30ms-1 in the field of view. The factors that will affect the quality of the interference fringe image are investigated including polarisation sensitivity of the two beam splitters and flatness of the optical components. The inclination angle and the optical path deviation have little effect on the contrast of the interference fringes since collimated light beams, rather than divergent ones, are used in the interferometer. 620.106

Search results