Global ETD Search

391	Virtual instrumentation: Introduction of virtual Ödlund, Erika January 2007 (has links) The Large Hadron Collider (LHC) is the next large particle accelerator developed at CERN, constructed to enable studies of particles. The acceleration of the particles is carried out using magnets operating at about 1.9 K, a temperature achieved by regulating flow of superfluid helium. For economical reasons, control of the helium flow is based on feedback of virtual flow meter (VFT) estimates instead of real instrumentation. The main purpose of this work is to develop a virtual flow meter with the possibility to estimate the flow by means of two different flow estimation methods; the Samson method that has previously been tested for the LHC, and the Sereg- Schlumberger method that has never before been implemented in this environment. The virtual flow meters are implemented on PLCs using temperature and pressure measurements as input data, and a tool for generating the virtual flow meters and connect them to the appropriate physical instrumentation has also been developed. The flow through a valve depends, among others, on some pressure and temperature dependent physical properties that are to be estimated with high accuracy. In this project, this is done by bilinear interpolation in twodimensional tables containing physical data, an approach that turned out to be more accurate than the previously used method with polynomial interpolation. The flow measurement methods have been compared. Since they both derive from empirical studies rather than physical relations it is quite futile to find theoretical correspondencies, but the simulations of the mass flows can be compared. For low pressures, the results are fairly equal but they differ more for higher pressures. The methods have not been validated against true flow rates since there were no real measurements available before the end of this project. / Le Grand Collisionneur de Hadrons (Large Hadron Collider, LHC) est le prochain grand accélérateur de particules du CERN, construit pour permettre l’étude des particules. L’accélération des particules sera réalisée en utilisant des aimants supraconducteurs qui fonctionneront à 1.9 K et la température sera régulée en contrôlant le débit d’hélium superfluide. Pour des raisons économiques, la régulation du débit d’hélium sera basée sur les réponses des estimations des débitmètres virtuels (Virtual flow meters, VFT) au lieu d’instrumentation réelle. Le but principal de ce projet est de développer un débitmètre virtuel qui estimera le débit avec deux méthodes différentes ; la méthode Samson qui a déjà été mise en oeuvre pour le LHC, et la méthode Sereg-Schlumberger qui n’a pas encore été implémentée dans cet environnement. Les débitmètres virtuels seront implémentés sur des PLCs avec des mesures de température et de pression comme données d’entrée. De plus, un outil pour générer les débitmètres et les relier avec l’instrumentation physique adéquat a été développé. Le débit à travers d’une vanne dépend entre autres des propriétés physiques qui dépendent à leur tour de la température et de la pression. Ces propriétés devront être estimées avec une grande précision. Dans ce projet, cela est fait en appliquant une interpolation bilinéaire dans des tableaux de deux dimensions. Cette méthode s’est montrée plus précise qu’avec une méthode d’interpolation polynomiale. Les deux méthodes de mesures de débit ont été comparées. Elles dérivent toutes les deux des études empiriques et non physiques, alors les similarités théoriques sont donc peu pertinentes, mais les résultats des simulations des débits peuvent être comparés. Pour des pressions basses, les méthodes sont quasiment équivalentes, mais les différences sont plus importantes pour les pressions plus hautes. Étant donné qu’il n’y avait pas de mesures disponibles avant la fin de ce projet, les méthodes n’ont pas été validées avec des débits réels. Flow meters LHC PLC Superfluid helium Virtual instrumentation Automatic control Reglerteknik
392	Studies of the Phenomenology of H+ → W+Z events with ATLAS at LHC Fleischhack, Henrike January 2012 (has links) The Higgs sector is the last part of the standard model of particle physics where we lack directexperimental results. Many extensions to the standard model describe an extended Higgs sector,often containing charged scalar bosons in addition to the standard model’s neutral Higgs boson.The H+WZ vertex can be used to distinguish between different non-standard Higgs sectors, andto measure the mass of the charged Higgs boson. In this report I will examine a promising searchchannels at the LHC and look at its phenomenology using monte carlo simulations. High energy physics particle physics Higgs boson charged Higgs boson LHC ATLAS
393	Search For Scalar And Tensor Unparticles In The Diphoton Final State In Cms Experiment At The Lhc Akin, Ilina Vasileva 01 September 2009 (has links) (PDF) We present a search for scalar and tensor unparticles in the diphoton final state produced in pp collisions at a center-of-mass energy of 10 TeV, with the CMS detector at LHC. The analysis focuses on the data sample corresponding to the integrated luminosity of 100 pb&amp / #8722 / 1, expected to be collected in the first LHC run. The exclusion limits on unparticle parameters, scaling dimension dU and coupling constant lambda, and the discovery potential for unparticles are presented. This is the first simulation study of the sensitivity to unparticles decaying into the diphoton final state at a hadron collider.
394	Production Of Z + Jet And Hf Jet Energy Scale Calibration At 7 Tev In The Cms Experiment At Lhc Bilin, Bugra 01 September 2011 (has links) (PDF) Forward Jet Calibration for CMS detector is presented using Z boson + jet event samples in the pseudorapidity region of 0 &lt / \|&eta / \| &lt / 5. The results are based on proton-proton collision data at center of mass energy of &radic / s = 7 TeV corresponding to &sim / 1 fb&minus / 1 of data. Z bosons are reconstructed from opposite sign lepton pairs (&mu / +&mu / &minus / , e+e&minus / ) and the transverse momentum balance of the Z boson and the associated jet is used to derive the calibration coefficients. The coefficients are tested on jets from a WW Monte Carlo sample using the W-mass constraint. The W mass peak position is observed to be improved by 20 % without loss of resolution. QC Elementary Particle Physics 793-793.5
395	Search For Z Sahin, Mehmet Ozgur 01 April 2012 (has links) (PDF) In this thesis, analysis of the forward backward asymmetry of high energy electron pairs at the CMS - LHC with a centre of mass energy of 7 TeV is presented and the possibility of search for a new neutral weak boson Z&rsquo / via measuring the forward backward asymmetry AFB of high energy electron pairs is discussed. The forward backward asymmetry is a natural result of the interference between the neutral current mediators: Photon and Z boson. A new neutral gauge boson would also interfere with these mediators and this new interference would either enhance the forward backward asymmetry at high energies or suppress it. In this analysis, 4.67 fb&minus / 1 data collected at the CMS experiment in 2011 is used QC Physics 1-999 Forward Backward Asymmetry, Z&rsquo boson, LHC, CMS, Dielectron
396	Open midplane designs based on sector coils in superconducting dipole magnets Bruér, Jens January 2008 (has links) <p>For some cases of lattice layout in particle accelerators, the major part of the energy deposition coming from the collision is located in the midplane of the magnets. The heat produced might result in a quench in superconducting magnets. One solution for reducing the energy deposition in the coil is to introduce an opening in the midplane, which will lead away most of the particles to a safe zone instead of hitting the superconductors in the magnets.</p><p>The aim of this work is to optimize the field quality in dipoles based on the cosθ-design, where an opening in the midplane has been inserted. The equations for finding the solutions for the coil layout for different sizes of the opening are studied, and the solution giving the best field quality for each case is presented. Then, optimization procedures are applied to lay-outs with Rutherford cables. Finally, the resulting field strength from the solutions obtained is presented.</p> Open midplane designs superconducting dipoles magnetic field quality CERN LHC Physics Fysik
397	Trigger à muons, étiquetage de la saveur et performances physiques de l'expérience LHCb Leroy, O. 10 October 2007 (has links) (PDF) Ce mémoire est une synthèse de mes activités postdoctorales au sein de l'expérience LHCb, en cours d'installation auprès du grand collisionneur de hadrons LHC au Cern, à Genève. Dans le chapitre 1, j'introduis les bases phénoménologiques nécessaires à l'étude de la physique des saveurs en montrant que cette dernière s'inscrit au coeur du modèle standard. Je rappelle les limitations de ce modèle. Puis j'explique comment la physique des saveurs en général, et plus particulièrement celle effectuée à LHCb, permet de rechercher de la nouvelle physique ou de la contraindre. Dans le chapitre 2, après une rapide présentation du détecteur LHCb, je présente le trigger de niveau zéro à muons, en développant deux aspects sur lesquels j'ai plus particulièrement travaillé: la résistance aux radiations des transmetteurs opto-électroniques et les performances physiques simulées du trigger. Le chapitre 3 synthétise les activités liées à l'étiquetage de la saveur des mésons B, activités dont je suis co-organisateur depuis mai 2005. Enfin au chapitre 4, après un rappel des progrès récents accomplis en physique des saveurs lourdes, je donne un aperçu des performances attendues de LHCb, pour quelques mesures clés. Je détaille notamment un aspect auquel j'ai pris part: la recherche de nouvelle physique dans les diagrammes pingouins b->s. LHC LHCb Physique du b étiquetage saveur trigger muons
398	Calorimetrie electromagnetique et mesures de precision avec le detecteur ATLAS aupres du collisionneur LHC Pralavorio, Pascal 27 June 2007 (has links) (PDF) Ce mémoire présente une synthèse des travaux que j'ai effectués depuis 9 ans pour la préparation de l'expérience ATLAS, devant fonctionner auprès du futur grand collisionneur de hadrons du CERN, le LHC, qui entrera en service en 2008. LHC ATLAS Calorimetre top W
399	Search for Weakly Produced Supersymmetric Particles in the ATLAS Experiment Tylmad, Maja January 2014 (has links) The Large Hadron Collider located at CERN is currently the most powerful particle accelerator and ATLAS is an experiment designed to exploit the high energy proton-proton collisions provided by the LHC. It opens a unique window to search for new physics at very high energy, such as supersymmetry, a postulated symmetry between fermions and bosons. Supersymmetry can provide a solution to the hierarchy problem and a candidate for Dark Matter. It also predicts the existence of new particles with masses around 1 TeV, thus reachable with the LHC. This thesis presents a new search for supersymmetry in a previously unexplored search channel, namely the production of charginos and neutralinos directly decaying to electroweak on-shell gauge bosons, with two leptons, jets, and missing transverse momentum in the final state. The search is performed with proton-proton collision data at a center of mass energy of √s = 8 TeV recorded with the ATLAS experiment in 2012. The design of a signal region sensitive to the new signal is presented and a data driven technique to estimate the Z+jets background is developed. Precise measurements of hadronic jet energies are crucial to search for new physics with ATLAS. A precise energy measurement of hadronic jets requires detailed knowledge of the pulse-shapes from the hadron calorimeter signals. Performance of the ATLAS Tile Calorimeter in this respect is presented using both pion test-beams and proton–proton collision data. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2 and Paper 4: Technical report from the ATLAS experiment.</p> ATLAS ATLAS experiment supersymmetry chargino neutralino physics analysis LHC Large Hadron Collider
400	Extraction and Validation of the FIDEL Field Model Parameters for the Main Dipoles of the LHC / Extrahering och Validering av FIDEL-Fältmodellparametrarna för dipolerna i LHC Sernelius, David January 2007 (has links) The Large Hadron Collider (LHC) is presently under construction at CERN. The LHC is a circular accelerator that stores proton beams and accelerates them to a 7 TeV beam energy for high energy physics research. The required bending and focusing/defocusing fields are achieved with superconducting magnets. Such a superconducting magnet-based accelerator can be controlled only when the field errors of production and installation of all magnetic elements are known to the required accuracy. The ideal way to compensate the field errors is to have direct diagnostics on the beam. For the LHC, however, a system solely based on beam feedback may be too demanding. The present baseline for the LHC control system hence requires an accurate forecast of the magnetic field and the multipole field errors to reduce the burden on the beam-based feedback. The field model is the core of this magnetic prediction system, also known as \emph{the Field Description for the LHC} (FIDEL). The model will provide the forecast of the magnetic field at a given time, magnet operating current, magnet ramp rate, magnet temperature, and magnet powering history. The model is based on the identification and physical decomposition of the effects that contribute to the total field in the magnet aperture of the LHC dipoles. This thesis presents the tool that was constructed to ease the detection, identification and finally correction of errors in the raw data from the series measurements of the main dipoles of the LHC. The results after cleaning all measurement data for the over 240 dipoles measured at cold, using this tool, is also presented. Another aspect of the Thesis is the presentation of a procedure devised to extract the model parameters for the main dipole magnets of the LHC by using the cleaned data. The procedure and the model are verified and validated by application to the magnets of the 7-8 sector of the LHC. CERN LHC Dipole FiDEL Field model Parameters Magnets Measurements Superconducting Physics Fysik

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