Variation of the Carbon Isotope Composition in Some Natural Processes

Taylor, Edwin William

10 1900

The variation in the carbon isotope composition of the cap rock of Texas and Louisiana sulphur wells was investigated by means of a simultaneous collection mass spectrometer. These rocks showed anomalously large depletions in C-13. The isotope depletion in the decarboxylation of pyruvic acid, both by chemical means and by bacteria, was measured and the isotope composition of the carbon dioxide released was found to be similar to that of the cap rock. The hypothesis is advanced that the carbonate of the cap rock may have originated by the precipitation of carbon dioxide released in the bacterial decarboxylation of an organic substrate. / Thesis / Master of Science (MSc)

isotope

carbon

Texas

cap rock

sulphur wells

Louisiana

mass spectrometer

decarboxylation

High Speed Fiber Optic Spectrometer

Wang, Yongxin

27 December 2007

This dissertation presents the structure, operational principle and mathematical model of a novel high speed fiber optic spectrometer (HSFOS). In addition, the performance analysis is conducted and preliminary experimental results are listed and discussed. Such a spectrometer is highly desired by the ever-increasing applications of fiber optic sensors. In the recent decades, a variety of fiber optic sensors have been proposed, built and tested. Compared to their electronic counterparts, fiber optic sensors although still under development, are preferred more by certain industrial and medical applications which benefit from their unique properties such as immunity to electromagnetic interference, ability to withstand harsh environments and composition of purely dielectric materials. In recent years, new fiber optic sensors have been designed for applications where high response frequency up to a few hundred KHz is required while advantages of high accuracy and large dynamic range must be maintained. The bottle neck then emerged in the signal demodulation part of the sensor system. The quadrature phase detection could achieve high demodulation speed but with small dynamic range, medium accuracy and measurement ambiguity. The white light interferometry could provide a solution for high accuracy and large dynamic range measurement without ambiguity because of its absolute measurement nature. However the signal demodulation speed is limited due to the low spectrum acquisition rate of the existing spectrometers. The new HSFOS utilizes time domain dispersion of the sampled incoming light by dispersive fiber rather than the spatial dispersion employed by traditional spectrometers. In addition the signal that represents the spectrum of the light is naturally a serial signal which can be detected by a single detector and recorded by a high speed data acquisition device. Theoretical study of the operation principle is made and a mathematical model for the spectrometer is developed based on Marcuse's previous work. One major difference of the new derivation is that the propagation constant is expanded about the center circular frequency of each monochromatic light pulse instead of the center frequency of the chromatic light pulse which makes the physical picture of the chromatic light pulse evolution in a dispersive fiber clearer and facilitates both the analytical and numerical analysis. The profile of the dispersed chromatic light pulse could be treated as the superposition of all the dispersed monochromatic light pulses. Another major difference is the Taylor's series of the propagation constant is not truncated as it is in those previous work, which improves the accuracy of the model. Moreover, an approximate model is made which could further reduce the computation tasks in numerical simulations. Performance analysis for accuracy, resolution, speed and noise are conducted through numerical simulations based on the model and the experimental results. The sources of two different errors and their effects on accuracy are discussed respectively. The effects on spectral resolution by the properties of the modulation pulse and the fiber dispersion are studied. The results indicate that by using a rectangle modulation pulse under certain conditions, the resolution can be improved. The speed analysis gives that the spectrum acquisition rate can reach 1 million frames per second when the spectral width is less than 100 nm. In the noise analysis, the erbium-doped fiber amplifier (EDFA) is determined to be the dominant noise source. But by using two EDFAs, the overall signal to noise ratio is improved by 9.2 dB. The preliminary experimental results for FP sensor and FBG sensor signal demodulation are presented. The HSFOS for FP sensor signal demodulation achieves 15 nm resolution. By using the oversampling method, the HSFOS for FBG sensor signal demodulation achieves 0.05 nm spectral positioning resolution. / Ph. D.

Spectrometer

Fiber Optic Sensor

Fiber Optics

Signal processing

Spectroscopy

Spectroscope

Spectrometry

(e,2e) spectroscopic investigations of the spectral momentum densities of thin carbon films

Dennison, John Robert

January 1985

An (e,2e) electron scattering spectrometer has been constructed and used for the first time to investigate the spectral momentum density of the valence bands of a solid target. This technique provides fundamental information about the electronic structure of both crystalline and amorphous solids. The three fundamental quantities, the band structure, electron density of states, and electron momentum distribution can be simultaneously derived from the measured (e,2e) cross section. A review of single electron and (e,2e) scattering theory is given with an emphasis on scattering from solids. The effects of multiple scattering are discussed and a method of deconvoluting those effects from the measured (e,2e) cross section is developed. There is a detailed description of the spectrometer design and operation with particular attention given to the electron optics and voltage distribution. The algorithms and software for computer aided data acquisition and analysis are also outlined, as is error analysis. The techniques employed in the preparation and characterization of extremely thin film samples of a-C and single crystal graphite are described. An analysis of the data taken for a-C samples is given. The data are compared with the results of complementary experiments and theory for graphite, diamond, and a-C which are given in a review of the literature. The existence of a definite dispersion relation ε(q) in amorphous carbon is demonstrated. The a-C band structure appears to be more similar to that of graphite than to that of diamond, however it differs significantly from both in some respects. The measured spectral momentum density seems compatible with a model of a-C based on small, randomly-oriented islands of quasi-2D graphite-like continuous random network structures. However, no definitive interpretations can be made until higher resolution experiments are performed on both a-C and single crystal graphite. / Ph. D.

LD5655.V856 1985.D468

Electron spectroscopy

Spectrometer -- Design and construction

Carbon -- Spectra

Electrons -- Scattering

Search for evidence of fermi surface nesting in Bi₂Sr₂Ca₁Cu₂O₈

Potter, Charles D.

21 October 2005

The electron energy loss spectrometer at Virginia Tech has been modified with new momentum deflectors and various other hardware improvements. In addition to some hardware changes all the software to run the spectrometer and analyze the data has been rewritten. It was suggested by Tsuei (1990) that a nested Fermi surface could be used to explain both the fact that these materials have high superconducting transition temperatures and have linear relaxation rates. It was suggested in that same paper that EELS might be able to confirm the presence of Fermi surface nesting. We have attempted to use transmission electron energy loss spectroscopy in a novel way to search for evidence of Fermi surface nesting in the high T_c superconductor Bi₂Sr₂Ca₁Cu₂O₈. High quality single crystal samples were obtained and thinned for use in the EELS. Data was taken at low energy (<1.0eV) and momentum was scanned along three different momentum transfer directions for |q| =0.0 to 3.0Å⁻¹. The data was scaled to be Im(-1/ε). A calculation of Im(-1/ε) was performed using a tight binding model and it was found that the features associated with the Fermi surface (from this TB calculation) were too small to be seen in our spectra. We interpret this problem to be associated with the presence of thermal diffuse scattering. / Ph. D.

LD5655.V856 1992.P677

Fermi surfaces

Interacting boson-fermion models

Spectrometer

Superconductors

Thermal neutrons -- Scattering

The amplification of twisted light in multimode optical fibers

Peterson-Greenberg, Aaron

29 January 2025

2025 / The development of fiber amplifiers plays a critical role in a wide range of applications, including high-energy systems, weak signal sensing and imaging, and optical communications, where Erbium-doped fiber amplifiers (EDFAs) are commonly utilized. In particular, the increasing demand for amplifiers capable of supporting a high number of data channels is essential to avoid the looming “capacity crunch” in information networks. However, any significant expansion in capacity will inevitably drive a substantial rise in energy consumption. Consequently, the integration of additional data channels in telecommunications must be approached with energy efficiency in mind. Spatial division multiplexing (SDM) has emerged as a promising solution, leveraging spatial dimensions such as modes or fiber cores to enable data parallelism, and is becoming the preferred technology for reducing energy usage in optical networks. This thesis examines the amplification dynamics and properties of multimode (MMF) ring-core fibers (RCFs) that can stably support spatial modes carrying orbital angular momentum (OAM), which can serve as independent, uncoupled signal channels. Notably, RCFs featuring topologically confined modes (TCMs) have demonstrated the highest uncoupled mode capacity among MMFs to date. We explore how these fibers can be turned into amplifiers by utilizing χ^(3) material nonlinearities and by developing doped MMF-EDFAs.In this work, we investigate the nonlinear effects of OAM modes in multimode fibers, with a particular focus on acousto-optic interactions between these modes and phonons, leading to the generation of Stimulated Brillouin Scattering (SBS). Traditionally, SBS in single-mode fiber amplifies a narrowband Stokes signal using a powerful pump, operating through a self-phase matching process. However, by utilizing OAM modes, we exploit their distinctive phase characteristics to exert greater control over this interaction. This leads to the introduction of a novel OAM conservation law, which governs the modulation of inter-modal interactions between the pump, phonons, and Stokes, allowing for adjustable nonlinear gain. Furthermore, the chiral properties of OAM modes enable the launch of superposition-state pumps in RCFs, resulting in polarization rotation, a phenomenon known as optical activity. This optical activity, characterized as a stable birefringent interference effect due to its geometrodynamic nature, creates a special phase-matching and polarization-selective condition. This condition allows for complete spatial phase conjugation of the pump state, as the Stokes signal must retrace the pump’s polarization rotation to achieve significant gain. This mechanism also provides control over Stokes growth and the gain threshold condition. Overall, our analysis demonstrates that OAM modes offer up a versatile degree of freedom for controlling amplification through fiber nonlinearities. RCFs and OAM modes present significant potential for developing high-data-capacity SDM-EDFAs, offering key advantages for stimulated emission-based amplification. The strong confinement of these modes within a doped fiber core enhances their interaction with erbium ions, facilitating the creation of highly absorbing and emitting amplifiers that outperform their single-mode and multi-core EDFA counterparts. Another benefit of using OAM modes lies in their similar intensity profiles, with their orthogonality primarily derived from distinct phase characteristics. Since EDFA amplification depends on intensity rather than phase, this architecture enables high, equalized gain and low-noise amplification across numerous spatial channels. We experimentally characterize an RCF-EDFA that leverages these advantages and topological confinement to achieve high-gain amplification across a record number of uncoupled OAM modal channels. Furthermore, simulations of an optimized, deployment-ready version of the EDFA further demonstrate its ability to amplify numerous spectral and spatial data channels simultaneously while maintaining high energy efficiency. This performance is made possible through a proposed pumping scheme in which the pump consists of a superposition of OAM fiber modes, like the signal, benefiting from the large and stable mode ensemble. By sculpting the modal distribution of the pump, the amplifier architecture is optimized to increase pump-signal overlap, achieving both high, equalized gain and low noise figures while reducing pump power requirements. This thesis explores this parameter space, through both simulations and experimental investigations, with the aim of developing optimal SDM fiber amplifiers that address the capacity, energy efficiency, and cost demands of future optical fiber networks.

Optics

Nonlinear optics

Optical rotary dispersion

Pump sculpting

Spectrometer

Structured light

Wavemeter

Magnetic resonance studies of issues critical to solid state quantum computer

Suwuntanasarn, Nakorn, Physical, Environmental & Mathematical Sciences, Australian Defence Force Academy, UNSW

January 2008

The spins of phosphorus doped in silicon are potential candidates for a quantum computing device, with models based on the use of nuclear and/or electron spins suggested. For a quantum computing device, several essential criteria must be demonstrated before any physical implementation, and these include qubit control gates, long decoherence time and scalability. Scalability and compatibility with existing fabrication technologies are strong points in favour of a silicon based system. For spin based schemes, silicon has the potential to provide a host with zero nuclear spin (isotopically purifed 28Si) and also the phosphorus donor provides both nuclear and electron half integer spins (ideal case). In this work, a magnetic resonance method (electron spin resonance) was utilised to investigate these critical issues (controllable quantum gates and decoherence time) for the electron spins of phosphorus donors in silicon. Electron spin resonance (ESR) studies of an ensemble of phosphorus electron spins in silicon were conducted via both continuous wave and pulsed methods. For pulsed ESR operations, two low temperature (4 K and millikelvin) X-band pulsed ESR systems were built. They were designed especially to suit Si:P decoherence time measurements. The design, modelling, construction and evaluation of the probe heads are described. With the aid of computer simulations, the performance of the probe heads was optimised and a rectangular loop gap resonator was found to be the most suitable for wafer type samples. The resonant frequency, quality factor, and coupling coeffcient were calculated via simulation and are in reasonable agreement with experimental results. This demonstrates the effectiveness of such simulations as a tool for optimising the probe head performance. A millikelvin pulsed ESR system was set up through the combination of a dilution refrigerator, superconducting magnet and the in-house construction of a pulsed ESR spectrometer. This novel system allows pulsed ESR experiments on an ensemble system to be realised down to the millikelvin temperature range, hence providing conditions considered most favourable for quantum computing studies. The use of light in combination with the pulsed ESR systems was also explored in an endeavour to overcome the problem of very long spin-lattice relaxation time, T1, allowing the decoherence time to be measured more effciently. With these novel low temperature pulsed ESR units, two-pulse electron spin echo experiments were conducted on phosphorus donors in silicon (both natural silicon (natSi) and 28Si) with the phosphorus concentration in the range of 1015- 1016 P/cm3 and to lower temperatures than previously investigated. Decoherence times measured for both natSi:P and 28Si:P (with similar donor concentrations) were longer than previously reported. Discussions on several effective ways to obtain even longer Si:P decoherence times including variations to sample configurations and experimental conditions are presented. In addition to the pulsed ESR studies, the Si:P controllable quantum gate functions, A gate and J gate, were examined by the continuous wave technique via Stark shift and exchange interaction experiments respectively. Stark shift experiments on bulk samples were carried out to investigate possible manipulation of the spins by the applied electric field. Continuous wave ESR was also used to examine low energy ion implanted Si:P devices, both by single (P+) and dimer (P+2 ) implanted donors. The outcomes from these studies provide materials information useful in formulating a strategy toward the Si:P device fabrication via the top down approach.

Solid state quantum computer

Magnetic resonance

4 K probe head

High Resolution Infrared Spectroscopy : Setting up an experiment to investigate small clusters/ Spectroscopie Infrarouge à Haute Résolution: Mise au point d'un dispositif expérimental pour l'étude des petits agrégats

Didriche, Keevin

06 November 2008

The role of clusters in planetary atmospheres and the interstellar medium is potentially important. Investigating such a role requires basic experimental information, however lacking. The goal of this thesis was to develop an efficient experimental set-up to produce clusters in the laboratory in concentrations large enough to allow their high resolution spectra to be recorded, thus providing the necessary data allowing the physico-chemical properties of the clusters to be studied. The study of this subject however suffers from the lack of basic experimental data. The goal is therefore to produce clusters in the laboratory in concentration large enough to record their high resolution spectrum. This is the initial aim of the present thesis. During this work, we have built and extensively tested a new experimental set-up called FANTASIO (``Fourier trANsform, Tunable diode and quadrupole mAss spectrometers interfaced to a Supersonic expansIOn'). With the help of this new device, various experiments on jet-cooled species have been performed. The cartography of the supersonic expansion was established, using the mass spectrometer as a moving pressure probe. This enabled us to characterize the geometrical properties of the supersonic jet produced by circular and slit nozzles and to determine the position of the virtual nozzle. The effect of the axisymmetric expansion geometry on the R(0) lineshape in the nu_3 band of N_2O, recorded by FTIR, was also investigated. The rotational temperature of the jet-cooled molecules was determined to be a few K by measuring the intensity of lines in spectra recorded by FTIR spectroscopy. Vibrational energy transfer occuring in the expansion between N_2O molecules and different collision partners was investigated on the nu_2+nu_3-nu_2 band of N_2O, again using FTIR spectroscopy. The trend of these transfers was found to be related to the energy difference between the v_2=1 level of N_2O and the closest vibrational state in the collision partner, with the largest population. The sensitivity of the set-up was enhanced by a factor of 5 by increasing the absorption path length, using a multipass system. A procedure to remove the residual gas contribution from the IR spectra was developped, based on the mass spectrometer. Thanks to this sensitivity increase, broadband absorption features of clusters were observed for a C_2H_2-Ar mixture in circular and slit expansions. The optical sensitivity of FANTASIO was again increased by the implementation of the CW-CRDS system. The enhancement over FTIR was calculated to be over a factor 750. Thanks to this drastic improvement, spectral signatures of various clusters were recorded, such as C_2H_2-Ar, C_2H_2 multimers, C_2H_2-N_2O and C_2H_2-CO_2, at high resolution. The role of clustering in generating unusual line shapes of acetylene in an axisymmetric expansion was investigated. We demonstrated that C_2H_2 aggregates produced in the expansion are responsible for central dips observed in the monomer absorption. These acetylene clusters thus appear to be formed in the centre of the expansion, while, unexpectedly, acetylene-Ar complexes are formed at the edge of the conical expansion. Various research prospects were explored during this thesis thanks to the FANTASIO device, opening new research directions. FANTASIO is today operational and defines a useful tool to achieve the study of small clusters by infrared spectroscopy./ Le rôle des agrégats dans les atmosphères planétaires et dans le milieu interstellaire est potentiellement important. Cependant, les études sur ce sujet souffrent du manque de données expérimentales. Le but de cette thèse était de développer un dispositif expérimental efficace pour produire au laboratoire des agrégats en quantité suffisante pour permettre l'enregistrement de leur spectre infrarouge à haute résolution et donc l'étude de leurs propriétés physico-chimiques. Durant ce travail, nous avons construit et testé un nouveau dispositif expérimental appelé FANTASIO, basé sur un jet supersonique couplé à un spectromètre de masse, un spectromètre à transformée de Fourier et un système CRDS. Grâce à cet appareillage, différentes expériences sur des molécules à basse température ont été menées. L'expansion supersonique a été cartographiée en utilisant le spectromètre de masse comme une sonde de pression mobile. Cette cartographie nous a permis d'établir les propriétés géométriques des jets supersoniques produits par les orifices circulaire et de type fente, et de déterminer la position de l'orifice virtuel. L'effet de la géométrie de l'expansion sphérique sur le profil de la raie R(0) de la bande nu_3 de N_2O, enregistré par FTIR, a aussi été étudié. Une température rotationnelle de quelques K a été déterminée pour les molécules refroidies en jet supersonique par mesure de la distribution d'intensité de raies dans les spectres enregistrés par FTIR. Le transfert d'énergie vibrationnelle entre des molécules de N_2O et différents partenaires collisionnels a été étudié en analysant l'intensité de la bande nu_2+nu_3-nu_2 de N_2O, enregistré également par spectroscopie FTIR. Il a été trouvé que la tendance de ces transferts est liée à la différence d'énergie entre le niveau v_2=1 de N_2O et l'état vibrationnel le plus proche et le plus peuplé du partenaire collisionnel. La sensibilité du dispositif a été augmentée d'un facteur 5 dû à l'allongement du chemin d'absorption, grâce à l'utilisation d'un système multipassage. Une procédure basée sur l'utilisation du spectromètre de masse et visant à enlever la contribution du gaz chaud résiduel dans les spectres infrarouges a été mise au point. Grâce à cette augmentation de sensibilité, des structures d'absorption non résolues d'agrégats ont été observées dans des expansions en trou et en fente d'un mélange de C_2H_2-Ar. La sensibilité optique de FANTASIO a encore été augmentée par l'ajout au dispositif d'un système CW-CRDS. L'amélioration par rapport au spectromètre à transformée de Fourier a été calculée comme étant supérieure à un facteur 750. Grâce à cette importante amélioration, les signatures spectrales de divers agrégats, tels que C_2H_2-Ar, des multimères de C_2H_2, C_2H_2-N_2O et C_2H_2-CO_2, ont été enregistrées à haute résolution. Le rôle de l'agrégation dans la génération de profils de raie inhabituels dans une expansion en trou de l'acétylène a été étudié. Nous avons démontré que les agrégats de C_2H_2 produits dans le jet supersonique sont responsables des creux observés dans le profil d'absorption du monomère. Ces agrégats apparaissent donc comme étant formés au centre de l'expansion, tandis que, de manière inattendue, les agrégats de C_2H_2-Ar sont formés aux bords de l'expansion conique. Plusieurs idées de recherche ont été explorées durant cette thèse grâce au dispositif FANTASIO, ouvrant de nouvelles directions de recherche. FANTASIO est aujourd'hui opérationnel et se présente comme un outil utile dans l'étude des petits agrégats par spectroscopie infrarouge.

dispositif expérimental

spectroscopy

spectroscopie

infrarouge

infrared

cluster

agrégats

haute résolution

high resolution

supersonic jet

jet supersonique

Fourier spectrometer

set-up

spectromètre à transformée de Fourier

FTIR

CRDS

Fantasio

mass spectrometer

spectromètre de masse

Rotational Spectroscopic And Ab Initio Studies On The Weakly Bound Complexes Containing 0-H...π And S-H...π Interactions

Goswami, Mausumi

07 1900

Work reported in this thesis mainly comprises of the assignments and analysis of the rotational spectra and structures of three weakly bound complexes: C2H4•••H2S, C6H5CCH•••H2O and C6H5CCH•••H2S. All the data have been collected using a home built Pulsed Nozzle Fourier Transform Microwave Spectrometer. Apart from this, the thesis also deals with a criterion of classifying a weakly bound complex to a ‘hydrogen-bonded’ one. First chapter of the thesis gives a brief intermolecular interactions and molecular clusters of π system. It also briefly touches on the structural determination by rotational spectroscopy and the basic information one can gain from the rotational spectrum. Second chapter of the thesis gives a brief introduction to the experimental and theoretical methodology. It also gives a description of the software used in the FTMW spectrometer which was rebuilt using Labview 7.1. Third chapter of the thesis deals with the rotational spectra and structure of eight isotopologoues of C2H4•••H2S complex. The lines are split into four components for the parent isotopologue due to the presence of large amplitude motion. The smaller splitting is 0.14 MHz and the higher splitting is 1.67 MHz in (B+C)/2 for the parent isotopologue. Spectral splitting pattern of the isotopologues confirmed that smaller splitting is due to the rotation of ethylene about its C-C bond axis along with the contraction of S-H bond whereas the larger motion arises due to the interchange of equivalent hydrogens of H2S in the complex. A detailed spectral analysis and ab initio calculation for this system have been described in chapter III. The fourth chapter of the thesis describes the rotational spectroscopic studies of five isotopologues of C6H5CCH•••H2O complex. Rotational spectra unequivocally confirm the structure of the complex to be a one where H2O is donating one of its hydrogen to the acetylenic π cloud forming a O-H••• π bond whereas the ring ortho C-H bond forms C-H•••O bond with the water oxygen. For theparent isotopomer the lines are split into two components due to the rotation of H2O about its C2 symmetric axis. The fifth chapter of thesis describes the rotational spectroscopic and ab initio studies of five isotopologues of C6H5CCH•••H2S complex. Rotational spectra indicate the structure to be the one where H2S is sitting on the top of the phenyl ring and shifted towards the acetylenic group. The sixth chapter of the thesis describes a criterion for calling a complex to be hydrogen bonded based on the dynamic structure rather than the static structure of the complex. The question asked is if the anisotropy of the interaction is strong enough to hold the ‘hydrogen bond’ when one takes dynamics into account. The proposed criterion is that the zero point energy of the motion which takes the hydrogen away from the acceptor should be much less than the barrier height of the respective motion supporting at least one bound level below the barrier. Ab initio calculations have been done on four model systems Ar2•••H2O, Ar2•••H2S, C2H4••• H2O and C2H4••• H2S to emphasize this criterion.

Hydroxy Compounds - Spectroscopy

Weakly Bound Complexes

Intermolecular Interactions

Hydrogen Bonding

Microwave Spectroscopy

PNFTMW Spectrometer

Rotational Spectra

Van der Waals Interaction

Hydrogen Bond

C2H4-H2S Complex

Phenylacetylene-H2O complex

Phenylacetylene-H2S complex

Inorganic Chemistry

Axially Symmetric Equivalents Of Three-Dimensional Rf Ion Traps

Shareef, I Khader

08 1900

This thesis presents axially symmetric equivalents of three-dimensional rf ion traps. Miniaturization in mass spectrometry has focused on miniaturizing mass analyzers. Decrease in mass analyzer size facilitates reduction of the size of other components of a mass spectrometer, especially the radio frequency electronics and vacuum system. Miniaturized mass analyzers are made using advanced microfabrication techniques. Due to micromachining limitations, it is not possible to fabricate ion traps with exact axial symmetry. The motivation for this thesis is to investigate newer three-dimensional geometries which do not possess axial symmetry, but are equivalent in performance to axially symmetric ion traps. We introduce a 3D geometry called square ion trap(SIT) having a ring electrode made off our square shaped planar surfaces and square shaped endcap electrodes resembling a cuboid. Initially, a SIT geometry is taken and it will be investigated if this unknown 3D geometry can be made equivalent to a well characterized, axially symmetric ion trap like the CIT. The purpose of showing equivalence will be to understand the ion dynamics and fields inside the new 3D SIT. This thesis consists of five chapters. In Chapter 1, we present the necessary background information required to understand the operation of a mass spectrometer. The Paul trap geometry is introduced followed by the derivation of equation of ion motion inside the Paul trap. The Mathieu stability plot and the modes of operation of a mass spectrometer are briefly discussed. The chapter ends by outlining scope of the thesis. Chapter 2 describes the computational methods employed by us in the thesis. First, the geometry of square ion trap is introduced. Then the boundary element method(BEM) which is used to compute the charge distribution on the electrode surfaces is discussed. This is followed by the three-dimensional Green’s function which should be employed for non-axially symmetric structures. The method to calculate potential and field inside the ion trap from charge distribution is shown. Calculation of multipole coefficients for non-axially symmetric traps using charge distribution is shown. The methods used to generate ion trajectory and stability plot are discussed. The Nelder-Mead simplex method used for optimization is also presented. To verify our numerical methods of charge calculation, we have taken standard textbook problems and compared our results with those presented therein. The multipoles calculation, field and ion trajectory was verified by comparing the results for the Paul trap and cylindrical ion traps. Chapter 3 presents the results for axially symmetric equivalents of 3D rf ion traps. SIT geometry of dimensions equivalent to the CIT0 are taken and field and multipoles are studied in it. Then optimization is applied to create a CIT geometry equivalent to the SIT under study. Axial field and ion trajectory was compared and observed to be matching. Finally, stability plot was generated for both SIT and its equivalent CIT and was found to present a close match. Chapter 4 presents the numerical results obtained for three-dimensional rf ion trap equivalent of CIT. In this chapter, we have considered two standard geometries, the CIT0 and the CITopt. Optimization was applied to create SIT geometries equivalent to the CIT0 and the CITopt respectively. Comparison of fields and ion trajectory confirmed the fact that non-axially symmetric traps can be created equivalent to any axially symmetric ion trap. We have also considered another case of axially symmetric circular planar ion trap which has an annular ring electrode and two planar endcap electrodes. Square equivalent of circular planar trap was created by the optimizer and its equivalent was verified by ion trajectory comparison. Chapter 5 summarizes the thesis with a few concluding remarks.

Mass Spectroscopy

Radiofrequency Ion Traps

Axial Symmetry

Paul Trap Mass Spectrometer

Square Ion Trap (SIT)

Mass Spectrometer

Paul Trap Geometry

Paul Trap

rf Ion Traps

Cylindrical Ion Trap (CIT)

Instrumentation

Entwicklung zweier Spektrometer für laserbeschleunigte Protonenstrahlen

Richter, Tom

10 October 2013

Durch die Fokussierung eines ultrakurzen und hochintensiven Laserpulses auf ein Festkörpertarget können Pulse von Protonen und anderen positiv geladenen Ionen mit Teilchenenergien von einigen MeV pro Nukleon erzeugt werden. Die Charakterisierung dieser Teilchenstrahlung erfordert die Identifizierung der Ionenspezies und die Bestimmung ihrer spektralen Verteilung möglichst nach jedem Puls. Im Rahmen dieser Diplomarbeit wurden zwei Spektrometer entwickelt und am DRACO-Lasersystem des Forschungszentrums Dresden implementiert. Neben der Inbetriebnahme eines Thomson-Spektrometers mit einer Mikrokanalplatte und einem Fluoreszenzschirm als Auslese erfolgte die Entwicklung eines Flugzeitspektrometers. Die Verwendung einer Mikrokanalplatte mit nur 180ps Anstiegszeit als Signalverstärker sorgt darin für eine verbesserte Energieauflösung und einen flexibleren Einsatz im Experimentierbetrieb. Ein dem Flugzeitsignal überlagertes Störsignal, welches durch die Einstreuungen eines elektromagnetischen Impulses in den Aufbau verursacht wurde, konnte erfolgreich durch die Anwendung verschiedener Filter unterdrückt werden. Als Ergebnis dieser Arbeit steht eine anwendungsbereite Diagnostik für laserbeschleunigte Protonen und Ionen zur Verfügung. / By focusing an ultra-short high-intensity laser pulse on a solid target, pulses of protons and other positive charged ions with energies of several MeV per nucleon are generated. It is necessary to identify the species of those particles and obtain their energy spectra in a single-shot regime. Within this diploma thesis two spectrometers have been developed and implemented in the DRACO-laboratory of the Forschungszentrum Dresden. Besides a Thomson spectrometer with read-out via microchannel plate and phosphor screen, a time-of-flight spectrometer was developed. The usage of a microchannel plate with 180ps rise time as a signal amplifier leads therein to a better energy resolution and a more flexible handling in experimental operation. A noise signal generated by stray pick-up of an electromagnetic pulse and superimposing the time-of-flight signal was considerably reduced by the application of different filters. As a result of this work a ready-to-use diagnostic for laser accelerated protons and ions is available.

Thomson-Spektrometer

Flugzeitspektrometer

Laserteilchenbeschleunigung

Laserprotonenbeschleunigung

Mikrokanalplatte

Thomson spectrometer

time-of-flight spectrometer

laser proton acceleration

laser particle acceleration

microchannel plate

ddc:530

rvk:UN 6100

rvk:UO 6120

rvk:UM 3120

Spektrometer

Laser

Teilchenbeschleunigung

Proton