Global ETD Search

1	Polarized Ultracold Neutrons: their transport in diamond guides and potential to search for physics beyond the standard model Makela, Mark F. 16 February 2005 (has links) Experiments with polarized "ultracold neutrons" (UCN) offer a new way to measure the decay correlations of neutron beta decay; these correlations can be used to test the completeness of the Standard Model and predict physics beyond it. Ultracold neutrons are very low energy neutrons that can be trapped inside of material and magnetic bottles. The decay correlations in combination with the neutron and muon lifetimes experimentally find the first element (Vud) of the Cabibbo-Kobayashi-Maskawa (CKM) quark mixing matrix. The CKM matrix is a unitary transform between the mass and weak eigenstates of the d, s and b quarks; if the matrix is not unitary this would imply that the Standard Model is not complete. Currently the first row of the CKM matrix is over 2 sigma from unitarity and Vud is the largest component of the row. The UCNA experiment looks at the correlation between the polarization of the neutron and the momentum of the electron resulting from the beta decay of the neutron (the A-correlation). The keys to making a high precision measurement of A-correlation are a near 100% polarization of the neutrons that decay, low"backscatter electron detectors, and small, well characterized backgrounds. UCN can be 100% polarized by passing them through a seven Telsa magnetic field. The key to the UCNA experiment is keeping them polarized until they decay or are lost. This dissertation covers the development of guides that are minimally depolarizing and efficient transporters of UCN and their use in the UCNA experiment. The entire guide development process is covered from conception to manufacturing and testing. This process includes development of a pulsed laser deposition, diamond-like carbon coating system and materials studies of the resulting coatings. After the initial studies of the guide coating, meter"long sections of guide are tested with UCN to determine their depolarization and transport properties. The guide technology developed in this dissertation has been used in the entire UCNA experiment. Also, this technology is currently the state of the art for polarized and non-polarized UCN guide systems and it is being implemented in several new UCN experiments. / Ph. D. Pulsed Laser Deposition Polarized Neutron Guides Neutron Beta Decay Polarized Ultracold Neutrons Diamond-Like Carbon Standard Model Tests
2	Thin Films for the Transport of Polarized Ultracold Neutrons for Fundamental Symmetry Study Mammei, Russell Rene 24 August 2010 (has links) The use of ultracold neutrons (UCN) to study fundamental parameters such as the neutron lifetime and decay correlations in polarized neutron beta decay are poised to make significant contributions to our understand of the Standard Model and its extensions. To this end, the UCNA experiment is pursuing a precision measurement (0.2%) of the angular correlation between the neutron spin and the direction of emission of the electron in polarized neutron decay (the ``A'' asymmetry). The UCNA experiment makes use of the spallation-driven solid deuterium (SD2) UCN source at the Los Alamos Neutron Science Center (LANSCE). The UCN leave the source and are 100% polarized by passing through a strong magnetic field before their decay is observed by a very sensitive electron spectrometer. UCN guides facilitate the transfer of UCN from the source to the spectrometer. Common guide materials include stainless steel, copper, aluminum, and quartz. Often a thin film is applied to these components to increase their ability to transport/bottle and preserve the polarization of UCN. In the region of the SD2 UCN source, nickel-58 films are applied, whereas once the UCN are polarized, diamond-like carbon (DLC) films are employed. This dissertation covers the application, process developments, and characterization of these coatings. In addition a study concerning the surface finish resulting from the mechanical polishing and electropolishing of the guides that make up the UCNA beamline is presented. / Ph. D. Neutron Beta Decay Polarized Ultracold Neutrons Standard Model Tests Diamond-Like Carbon Polarized Neutron Guides Pulsed Laser Deposition Ebeam Evaporation Electropolishing Mechanical Polishing Surface Roughness
3	First Determination of the Electric Charge of the Top Quark and Studies of the Top Quark Pair Background to New Physics Hansson, Per January 2008 (has links) This thesis is concerned with experimental investigations of properties of the top quark and processes involving this particle. In the first part of the thesis, the first determination of the electric charge of the top quark is presented. The measurement was made using top quark pair events produced in proton-antiproton collisions recorded by the D0 detector at the Fermilab Tevatron. It is based on the reconstruction of the charge of the top quarks decay products from the dominant decay to a W boson and a b-quark. The method uses a jet charge algorithm, calibrated with data, to discriminate between b- and antib-quark jets. A constrained kinematic fit is also performed to resolve the ambiguities of the pairing of the top quark decay products and to extract the top quark electric charge. The result is in good agreement with the Standard Model top quark electric charge of 2e/3 and an upper limit of 0.8 at 90\% confidence level on the fraction of exotic quarks with charge 4e/3 in the data sample is obtained. The second part of the thesis concerns the estimation of the top quark pair background to searches for new physics, such as supersymmetry, with the ATLAS experiment at the CERN Large Hadron Collider. These searches will require a robust estimation of standard model backgrounds in order to make any claims of discovery or to exclude models of new physics. For searches with a final state signature characterized by two isolated charged leptons, multiple jets and large missing transverse energy the largest source of background is expected to be top quark pairs with leptonic decay of the two W bosons from the top quarks in the event. A data-driven method to estimate this contribution based on full kinematic reconstruction of the top quark pair events is studied using simulated proton-proton collisions. It is shown that the method is capable of estimating the top quark pair background to within 12% using data corresponding to approximately 1fb-1. The systematic uncertainty is of the order of 20% and, depending on the model, the contamination of signal events can potentially be large. / QC 20100730 experimental particle physics particle physics standard model tests dzero fermilab tevatron top quark top physics electric charge atlas cern lhc large hadron collider supersymmetry Elementary particle physics Elementarpartikelfysik Physics Fysik
4	Calculs théoriques de corrections nucléaires aux taux de transitions β super-permises pour les tests du Modèle Standard / Theoretical calculation of nuclear structure corrections to the superallowed Fermi β decay rates for the tests of the Standard Model Xayavong, Latsamy 14 December 2016 (has links) La conservation du courant faible vectoriel, connue par CVC est une des hypothèses fondamentales du Modèle Standard de l'interaction électrofaible. En revanche, la base théorique de cette hypothèse est seulement l'analogie avec la théorie de l'interaction électromagnétique et la question de sa validité reste posée. La CVC est vérifiable dans les transitions super-permises, 0+ → 0+, T = 1 car elle prédit que le grandeur Ft (≡ ft corrigée) de ces processus à basse énergie doit être indépendant des noyaux mis en jeu. Si la valeur unique de Ft est trouvée, on peut toute de suite déduire la constante du couplage vectorielle GV , reliée à │Vud│, la norme de l'élément le plus important de la matrice du mélange des quarks de Cabibbo-Kobayashi-Maskawa (CKM). Cet élément de matrice joue un rôle crucial dans le test de l'unitarité de la matrice CKM, une autre hypothèse de base du Modèle Standard. Actuellement, 14 transitions super-permises allant du 10C jusqu'au 74Rb sont expérimentalement connues avec une précision meilleure que 0:1%, Cela fait en sorte que l'accès à la constante de couplage est limité par les corrections théoriques, dues aux effets radiatifs et à la brisure de la symétrie d'isospin. Le principal propos de cette thèse est de ré-examiner la correction due au défaut du recouvrement entre les fonctions d'onde radiales de neutrons et celles de protons (ᵟRO) dans le cadre du modèle en couches. Nos calculs sont basés sur l'expansion des éléments de matrice de Fermi sur les états du noyau intermédiaire, développée précédemment par Towner et Hardy [1]. Cette méthode combine les fonctions d'onde radiales réalistes avec les données spectroscopiques obtenues par un calcul à large échelle, permettant ainsi d'aller au-delà des approches traditionnelles. Nous avons considéré 13 transitions super-permises, y comprises : 22Mg, 26Al, 26Si, 30S, 34Cl, 34Ar, 38K, 38Ca, 46V, 50Mn, 54Co, 62Ga et 66As. Les fonctions d'onde radiales sont déterminées avec un potentiel moyen réaliste, tel que le potentiel phénoménologique de Woods-Saxon (WS) ou le potentiel auto-cohérent de Hartree-Fock (HF) dérivé à partir d'une force effective de Skyrme. Les calculs ont été faits avec des différentes paramétrisations (2 paramétrisations WS et 3 forces de Skyrme) qui nous ont semblés être les meilleures et les plus appropriées à nos besoins. Dans un premier temps, des calculs par une méthode simple, sans prise en compte des états intermédiaires ont été réalisés. Avec le potentiel WS, les valeurs de ᵟRO obtenues sont fortement dépendantes de paramétrisation. Afin de clarifier cet effet, nous avons étudié en détail la sensibilité aux paramètres du potentiel avec une attention toute particulière apportée au terme isovectoriel et au terme coulombien. Cela a permis de mettre en évidence qu'une telle dépendance est entièrement dominée par le comportement isovectoriel du potentiel. Finalement, cette propriété inattendue a été bien maîtrisée par la procédure d'ajustement proposée. (...) / The conservation of the weak vector current, known as CVC is one of the fundamentalhypothesis of the Standard Model of the electroweak interaction. Nevertheless,the physics background of this hypothesis is nothing more than an analogyto the electromagnetic interaction's theory and the question of its validity remainsopen. The CVC is veri_able in the superallowed Fermi β-decays, 0+ → 0+, T = 1since it predicts that the Ft (≡ corrected ft) value of such low-energy processesmust be nucleus independent. Once the unique Ft value is found, one can immediatelydeduce the vector coupling constant GV , linked to │Vud, the norm of themost important element of the Cabibbo-Kobayashi-Maskawa (CKM) quark-mixingmatrix. This matrix element plays a crucial role in the test of the unitarity of theCKM matrix, another fundamental hypothesis of the Standard Model.Currently, 14 superallowed transitions ranging from 10C to 74Rb are known experimentally with the precision 0.1% or better. This results in a fact that this studyis now limited by the theoretical corrections, due to the radiative and the isospin symmetry-breaking effects. The aim of this thesis is to re-examine the correction due to mismatch between proton and neutron radial wave functions (ᵟRO) within the framework of shell model. We adopted the method recently developed by Towner and Hardy [1]. This method combines realistic radial wave functions with spectroscopic informations obtained from a large-scale shell-model calculation, thus allowing us to go beyond traditional shell-model approaches. In this work, we considered 13 superallowed transitions, including : 22Mg, 26Al, 26Si, 30S, 34Cl, 34Ar, 38K, 38Ca, 46V, 50Mn, 54Co, 62Ga et 66As. The radial wave functions were determined with a realistic single-particle potential, such as the phenomenological Woods-Saxon (WS) potential or the self-consistent Hartree-Fock (HF) mean field derived from an effective Skyrme force. We selected various parametrizations (2 parametrizations for WS and 3 Skyrme forces for HF) that seem to us to be appropriate for our purposes. First, we performed the calculations with a simple method, without taking into account the intermediate states. The result indicates that ᵟRO obtained from WS potential is strongly parametrization dependent. In order to clarify this effect, we studied profoundly the sensitivity to potential parameters, paying particular attention to the isovector and the Coulomb terms.This study provided evidence that such a dependence is entirely dominated by the isovector part of the potential. However, using our proposed adjustment procedure, this problem appears to be well under control. We also examined the surface terms adopted in the work of Towner and Hardy [1], the result showed that one of these terms (the term Vh(r)) is not compatible with our adjustment procedure. (...) Tests du Modèle Standard Hypothèse CVC Unitarité de la matrice CKM Transition β super-permise 0+ → 0+ Brisure de la symétrie d'isospin Modèle en couches Potentiel de Woods-Saxon Potentiel auto-cohérent de Hartree-Fock Standard Model tests CVC hypothesis Unitarity of the CKM matrix Superallowed Fermi β - decay 0+ → 0+ Isospin symmetry breaking Radial overlap correction Shell model Woods-Saxon potential Self-consistent Hartree-Fock potential

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