Global ETD Search

11	Développement d'un injecteur pour l'accélération laser plasma multi-étages / Design of an electron injector for multi-stages laser wakefield acceleration Audet, Thomas 10 November 2016 (has links) L’accélération laser plasma (ALP) est un mécanisme d’accélération de particules reposant sur l’interaction d’impulsions laser ultra-intenses, de l’ordre de quelques 10^{18} W/cm², avec un plasma. L’onde plasma générée dans le sillage de l’impulsion laser est associée à des champs électriques de grande amplitude (1 − 100 GV/m). Ces champs électriques de trois ordres de grandeurs supérieurs aux champs maximums supportés dans les cavités radiofréquences des accélérateurs conventionnels constituent le principal point fort de l’ALP, permettant d’envisager des accélérateurs de particules plus compacts. Un important travail pour améliorer les propriétés des paquets d’électrons générés par ALP, leur stabilité et la cadence de tir est cependant nécessaire pour rendre l’ALP compétitive en termes d’applications.Un moyen d’améliorer les propriétés des faisceaux d’électrons consiste à les accélérer dans un régime faiblement non linéaire en plusieurs étapes successives : l’ALP multi-étages. La source laser-plasma d’électrons, ou injecteur, doit générer des paquets d’électrons d’énergie modeste (50 − 100 MeV), de charge la plus importante possible, de faible dimension et de faible divergence. Les électrons doivent alors être injectés dans un second étage purement accélérateur dont l’objectif est d’augmenter leur énergie cinétique.L’objet de cette thèse est le développement d’un injecteur laser plasma pour l’ALP multi-étages. Dans le cadre d’une collaboration autour de l’equipex CILEX et du programme d’ALP à deux étages, un prototype d’injecteur a été construit, ELISA, reposant sur une cellule de gaz de longueur variable. La densité électronique du plasma, qui est un paramètre crucial pour le contrôle du faisceau d’électrons, a été caractérisée à la fois expérimentalement et numériquement. ELISA a été utilisée sur deux installations laser différentes, et les mécanismes physiques déterminant les paramètres des paquets d’électrons produits par ELISA ont été étudiés en fonction des nombreux paramètres expérimentaux. Une gamme de paramètres pertinents pour un injecteur laser plasma a été déterminée.Une ligne de transport et diagnostic magnétique a également été construite, implantée et testée sur l’installation UHI100 du CEA Saclay, permettant à la fois de caractériser plus finement les propriétés des paquets d’électrons générés par ELISA, mais aussi d’évaluer la qualité des paquets d’électrons transportés pour l’injection dans un second étage. / Laser wakefield acceleration (LWFA) is a particle acceleration process relying on the interaction between high intensity laser pulses, of the order of 10^{18} W/cm² and a plasma. The plasma wave generated in the laser wake sustain high amplitude electric fields (1-100 GV/m). Those electric fields are three orders of magnitude higher than maximum electric fields in radio frequency cavities and represent the main benefit of LWFA, allowing more compact acceleration. However improvements of the LWFA-produced electron bunches properties, stability and repetition rate are mandatory for LWFA to be usable for applications.A scheme to improve electron bunches properties and to potentially increase the repetition rate is multi-stage LWFA. The laser plasma electron source, called the injector, has to produce relatively low energy (50-100 MeV), but high charge, small size and low divergence electron bunches. Produced electron bunches then have to be transported and injected into a second stage to increase electron kinetic energy.The subject of this thesis is to study and design a laser wakefield electron injector for multi-stage LWFA. In the frame of CILEX and the two-stages LWFA program, a prototype of the injector was built : ELISA consisting in a variable length gas cell. The plasma electronic density, which is a critical parameter for the control of the electron bunches properties, was characterized both experimentally and numerically. ELISA was used at two different laser facilities and physical mechanisms linked to electron bunches properties were studied in function of experimental parameters. A range of experimental parameters suitable for an laser wakefield injector was determined.A magnetic transport and diagnostic line was also built, implemented and tested at the UHI100 laser facility of the CEA Saclay. It allowed a more precise characterization of electron bunches generated with ELISA as well as an estimation of the quality of transported electron bunches for their injection in a second laser wakefield stage. Laser Plasma Electrons Accélération Laser Wakefield Electrons Acceleration Plasma
12	Beam diagnostics for the Texas Petawatt Laser Wakefield Acceleration Project Bedacht, Stefan 20 September 2010 (has links) An overview of the beam diagnostics for the laser wakefield acceleration project at the Texas Petawatt Laser facility is presented. In this experiment, short and intense laser pulses of 165 fs and up to 190 J will be used to accelerate electrons up to the GeV energy range using laser wakefield acceleration. The density variation of the plasma generated in a helium gas cell will be measured with different optical detection systems such as frequency domain holography. Spectra of the transmitted laser beam and optical transition radiation will yield information about the energy transfer to the plasma and the energy of the electrons, respectively. In addition, a calorimeter will measure accelerated electron energies. Prior to the final experiment, preliminary frequency shift measurements and simulations on optical transition radiation were performed. / text LWFA Laser Wakefield Acceleration Texas Petawatt Laser Plasma Laser Particle Accelerator
13	Interaction of charged particle beams with plasmas Siemon, Carl Joseph 16 February 2015 (has links) This thesis focuses on the propagation of charged particle beams in plasmas, and is divided into two main parts. In the second chapter, a novel theoretical model for underdense electron beam propagation during the nonlinear stage of the resistive Weibel instability (WI) is presented and is used to calculate the stopping time of the beam. The model and supporting simulation results lead to the conclusion that the WI initially enhances beam deceleration but then reduces it when compared to a filamentation-suppressed beam (without WI), so that the overall stopping time of the beam is essentially unaffected by the instability. Using the theoretical model, a criterion is derived that determines when deceleration is no longer enhanced by the instability. We also demonstrate that exotic plasma return current distributions can be obtained within and outside of beam filaments that sharply contrast those observed in collisionless systems. For example, the plasma return current is reversed in selected areas. In the next chapter, a new method for initiating the modulation instability (MI) of a proton beam in a proton driver plasma wakefield accelerator using a short laser pulse preceding the beam is presented. A diffracting laser pulse is used to produce a plasma wave that provides a seeding modulation of the proton bunch with the period equal to that of the plasma wave. Using the envelope description of the proton beam, this method of seeding the MI is analytically compared with the earlier suggested seeding technique that involves an abrupt truncation of the proton bunch. The full kinetic simulation of a realistic proton bunch is used to validate the analytic results. It is further used to demonstrate that a plasma density ramp placed in the early stages of the laser-seeded MI leads to its stabilization, resulting in sustained accelerating electric fields (of order several hundred MV/m) over long propagation distances (100-1000 m). The final chapter describes a harmonic expansion formalism that attempts to explain the post-linear stage of the MI. The formalism is developed first, and then several crippling problems with it are identified. / text Weibel instability Modulation instability PDPWA Inertial confinement fusion
14	A house for the Governor settlement theory, the South Australian experiment, and the search for the first Government House / Copland, Gordon Arthur, January 2006 (has links) Thesis (M.A) -- Flinders University, Dept. of Archaeology. / Typescript (bound). Includes bibliographical references (leaves 408 - 425). Also available online.
15	Age, Origin and Mineral Resources of the Sams Creek/Wakefield Complex, Maryland Piedmont Graybill, Elizabeth A. 25 July 2012 (has links) No description available. Geology Sams Creek Wakefield Westminster Terrane Piedmont Rodinia Breakup Tonian Microbialite Rift
16	You Are What You Ate: Consuming the Past to Benefit the Present McCleery, I., Shearman, V., Buckberry, Jo 07 November 2016 (has links) Yes / You Are What You Ate was a British public engagement project funded by the Wellcome Trust between 2010 and 2014. It was a collaboration between the University of Leeds, the University of Bradford and Wakefield Council, especially its museums, schools and libraries, which aimed to use medieval food as a way to encourage reflection about modern food and lifestyle. The innovative project ran three exhibitions in Wakefield and Pontefract, a mobile exhibition, numerous schools and youth workshops, and a series of market stalls and osteology workshops for adults and children in the Yorkshire region. This article provides an overview of the project’s aims, activities, outcomes, including an analysis of how to evaluate them, and its legacy. Archaeology Food Nutrition Health Wakefield (UK) Public engagement Medieval food Education Diet History Osteoarchaeology Palaeopathology
17	Towards a free-electron laser driven by electrons from a laser-wakefield accelerator : simulations and bunch diagnostics Bajlekov, Svetoslav January 2011 (has links) This thesis presents results from two strands of work towards realizing a free-electron laser (FEL) driven by electron bunches generated by a laser-wakefield accelerator (LWFA). The first strand focuses on selecting operating parameters for such a light source, on the basis of currently achievable bunch parameters as well as near-term projections. The viability of LWFA-driven incoherent undulator sources producing nanojoule-level pulses of femtosecond duration at wavelengths of 5 nm and 0.5 nm is demonstrated. A study on the prospective operation of an FEL at 32 nm is carried out, on the basis of scaling laws and full 3-D time-dependent simulations. A working point is selected, based on realistic bunch parameters. At that working point saturation is expected to occur within a length of 1.6 m with peak power at the 0.1 GW-level. This level, as well as the stability of the amplification process, can be improved significantly by seeding the FEL with an external radiation source. In the context of FEL seeding, we study the ability of conventional simulation codes to correctly handle seeds from high-harmonic generation (HHG) sources, which have a broad bandwidth and temporal structure on the attosecond scale. Namely, they violate the slowly-varying envelope approximation (SVEA) that underpins the governing equations in conventional codes. For this purpose we develop a 1-D simulation code that works outside the SVEA. We carry out a set of benchmarks that lead us to conclude that conventional codes are adequately capable of simulating seeding with broadband radiation, which is in line with an analytical treatment of the interaction. The second strand of work is experimental, and focuses on on the use of coherent transition radiation (CTR) as an electron bunch diagnostic. The thesis presents results from two experimental campaigns at the MPI für Quantenoptik in Garching, Germany. We present the first set of single-shot measurements of CTR over a continuous wavelength range from 420 nm to 7 μm. Data over such a broad spectral range allows for the first reconstruction of the longitudinal profiles of electron bunches from a laser-wakefield accelerator, indicating full-width at half-maximum bunch lengths around 1.4 μm (4.7 fs), corresponding to peak currents of several kiloampères. The bunch profiles are reconstructed through the application of phase reconstruction algorithms that were initially developed for studying x-ray diffraction data, and are adapted here for the first time to the analysis of CTR data. The measurements allow for an analysis of acceleration dynamics, and suggest that upon depletion of the driving laser the accelerated bunch can itself drive a wake in which electrons are injected. High levels of coherence at optical wavelengths indicate the presence of an interaction between the bunch and the driving laser pulse. 621.366
18	Laser wakefield acceleration in tapered plasma channels : theory, simulation and experiment Rittershofer, Wolf January 2014 (has links) Laser-plasma accelerators are of great interest because of their ability to sustain extremely large acceleration gradients, enabling compact accelerating structures. Laser-plasma acceleration is realized by using a high-intensity short pulse laser to drive a large plasma wave or wakefield in an underdense plasma. This thesis considers the effect of axial plasma density upramps on laser wakefield acceleration. Theoretical groundwork shows that tapered plasma channels can be used to mitigate one of the main limitations of laser plasma acceleration, that is, dephasing of an electron beam with respect to the plasma wave. It is shown that it is possible to maintain an electron bunch at constant phase in the longitudinal electric fields of the laser wake field. This leads to an increased energy gain of an electron trapped in the wakefield. The required shape of the density slope is difficult to implement in experiments. Therefore, a linear density ramp is also considered which is predicted to also increase the energy gain beyond that possible in a uniform density plasma. Towards an experimental implementation it was studied how a suitable gas density profile can be established in a capillary. This was done employing simulations using the computational fluid dynamics tool kit OpenFoam and comparing these to measurements of the axial density profile based on Raman scattering. It was demonstrated that a linear density ramp could be established by applying different pressures on the capillary gas inlets. The dependence of the density profile on the capillary parameters, such as, capillary diameter and length and inlet diameter were also studied. The results of the simulations and the measurement showed excellent agreement and demonstrate that approximately linear density ramps can be generated by flowing gas along a capillary of constant cross-section Laser wakefield acceleration in plasmas with longitudinally varying density was investigated in an experiment at the Astra Laser at Rutherford Laboratories. The experiment utilised ionisation injection in order to operate in the mildly non-linear regime of laser-wakefield acceleration. The measured electron energies agree well with the theoretical predictions. It was demonstrated that an increase in the energy gain can be obtained by driving the accelerator in a ramped plasma, the electron spectrum is more narrow and the injected charge increases significantly. Measurements of the X-ray spectrum emitted by the betatron motion of the accelerated electron bunch allowed the transverse radius of the bunch to be deduced. These measurements showed that retrieved electron bunch radius is inversely proportional to the longitudinal density gradient, that is a plasma density upramp (downramp) has a decreased (increased) electron bunch radius. 539.7
19	Music Education for Social Justice: A Case Study of the North Park Middle School Band January 2013 (has links) abstract: The North Park Middle School Band, in Pico Rivera, California, is an exemplary model of a band program grounded in the principles of social justice. Three facets guide the program: Social Outreach, Cultural Outreach, and Kids Helping Kids. This qualitative study explores what led the director to create this program, its current structure as well as its historical development, and the impact the program is having on the students involved and the community to which they reach. Between the months of September and December 2012, I spent a total of three weeks with the students, parents, and the director of the North Park Band, Ron Wakefield. In that time, the students were observed during band rehearsals on typical school days. Additionally, I traveled with the band to three separate outreach concerts at the Los Angeles Veterans Healthcare Facility, nursing homes and assisted living centers, as well as the Isaiah House, a homeless shelter for women and children. I observed the students and their interactions with the residents of those facilities, and took detailed observation notes. In addition, a survey was distributed to students in the top two bands, interviews were conducted with current students and a former student, a parent and a former parent, and the director. The North Park Band program structure leads students to develop an unusually high level of responsibility. Students gain an understanding of current issues in society and demonstrate compassion towards other human beings. In many cases, the students discover a sense of life purpose through the program and feel that they have a responsibility to help their community. While a central focus of the program is on humanistic values, it is evident that the students also receive a quality music education. / Dissertation/Thesis / D.M.A. Music 2013 Music education Music Education Carrie Pawelski music music education Ron Wakefield social justice social justice in music education
20	Optimal beam loading in a nanocoulomb-class laser wakefield accelerator Couperus, Jurjen Pieter 20 November 2018 (has links) Laser plasma wakefield accelerators have seen tremendous progress in the last years, now capable of producing electron beams in the GeV energy range. The inherent few-femtoseconds short bunch duration of these accelerators leads to ultra-high peak-currents. Reducing the energy spread found in these accelerators, while scaling their output to hundreds of kiloampere peak current would stimulate the next generation of radiation sources covering high-field THz, high-brightness X-ray and -ray sources, compact free-electron lasers and laboratory-size beam-driven plasma accelerators. At such high currents, an accelerator operates in the beam loaded regime where the accelerating field is strongly modified by the self-fields of the injected bunch, potentially deteriorating key beam parameters. However, if appropriately controlled, the beam loading effect can be employed to improve the accelerator’s performance, specifically to reduce the energy spread. In this thesis the beam-loading effect is systematically studied at a quasi-monoenergetic nanocoulomb-class laser wakefield accelerator. For this purpose, a tailored scheme of the self-truncated ionisation injection process is introduced for the non-linear bubble regime. This scheme facilitates stable and tunable injection of high-charge electron bunches within a short and limited time-frame, ensuring low energy spread right after injection. Employing a three millimetres gas-jet acceleration medium and a moderate 150 TW short pulse laser system as driver, unprecedented charges of up to 0.5 nC within a quasi-monoenergetic peak and energies of ~0.5 GeV are achieved. Studying the beam loading mechanism, it is demonstrated that at the optimal loading condition, i.e. at a specific amount of injected charge, performance of the accelerator is optimised with a minimisation of the energy spread. At a relative energy spread of only 15%, the associated peak current is around 10 kA, while scaling this scheme to operate with a petawatt driver laser promises peak-currents up to 100 kA. info:eu-repo/classification/ddc/539 ddc:539

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