A search for neutral high-mass Higgs bosons decaying into pairs of hadronically decaying tau leptons in 13 TeV collisions recorded by the ATLAS detector

Pickering, Mark Andrew

January 2016

This thesis outlines the search for neutral Higgs bosons in a mass range of m_H/A = 200 GeV − 1.2 TeV, decaying to a pair of hadronically decaying tau leptons. The search is performed using √s = 13 TeV proton-proton collision data, corresponding to an integrated luminosity of 3.21 fb^-1, recorded by the ATLAS detector. No excess over the predicted Standard Model background is observed and upper limits are placed on the production cross section times branching fraction as a function of the mass of the scalar resonance. When combined with the results of the analysis where one of the tau leptons decays to either a muon or electron, the 95% confidence level upper limit on the cross section times branching fraction ranges from 1.4 pb at m_H/A = 200 GeV to 0.025 pb at m_H/A = 1.2 TeV for a scalar boson produced via gluon-gluon fusion, and 1.6 pb at m_H/A = 200 GeV to 0.028 pb at m_H/A = 1.2 TeV for a scalar boson produced via b-associated production. The results are interpreted in the Minimal Supersymmetric extension to the Standard Model (MSSM) as a limit on the value of tanβ, as a function of the mass of the neutral CP-odd MSSM Higgs boson. In the mmod+ scenario, the 95% confidence level upper limit is tanβ < 7.6 for m_A = 200 GeV, and tanβ < 47 for m_A = 1 TeV. For the mass range m_A > 500 GeV, the upper limit on tanβ is improved in comparison to previous ATLAS searches.

Direct Top Quark Decay Width Measurement in the tt Lepton+Jets Channel at 8 TeV with the ATLAS Experiment

Stolte-Cord to Krax, Philipp

24 October 2017

No description available.

530

Physik (PPN621336750)

Particle Physics

ATLAS Experiment

Top Quark Physics

Top Quark Decay Width

Časové rozlišení TileCalu a hledání těžkých dlouhožijících částic / Time resolution of TileCal and searches for heavy metastable particles

Pagáčová, Martina

January 2012

Title: Time resolution of TileCal and searches for heavy metastable parti- cles Author: Martina Pagáčová Department: Institute of Particle and Nuclear Physics Supervisor: Doc. RNDr. Rupert Leitner, DrSc. Supervisor's e-mail address: Rupert.Leitner@cern.ch Abstract: In the present work, the timing of the ATLAS TileCal is stud- ied using the single hadron collision data. The time resolution and also the mean time response depend on the energy deposited in a given cell. The results are compared to the previous analysis with jets and muons. Precise time-of-flight measurement using TileCal can be used to identify the heavy long-lived particles predicted by the models of physics beyond the standard model. Their mass can be reconstructed by combining with the momentum measurement in the ATLAS inner detector. Finally, the mass resolution of an exotic particle with mass M = 600 GeV is estimated. Keywords: ATLAS experiment, TileCal, time resolution, stable massive particles

Analýza dat ze svazkových testů kalorimetru Tilecal / Tile Calorimeter testbeam data analysis

Uhliarová, Lea

January 2020

Tile Calorimeter modules are regularly tested in the CERN SPS North Area, as they are an integral part of the ATLAS experiment at the Large Hadron Collider at CERN. In this thesis, test beam data from November 2018 were used for two separate analyses. Muon SPS H8 beam allowed for the review of radial electromagnetic cali- bration in the extended barrel module EBC65. Data from November 2018 test beam confirmed the correctness of previously established and used constants for rectifying uneven response in A, BC and D cell rows. In the second analysis, hadron beam from the SPS accelerator impinging on the Tile Calorimeter modules in the projective geometry was utilized. It served to determine the distribution of the mean energy in the calorimeter for hadronic showers in Tile Calorimeter at η varying from −0.05 up to −0.65. 1

Measurement of the $W$ Boson Polarisation in $t\bar{t}$ Dilepton Events at $\sqrt{s}=8$ TeV with the ATLAS Detector

Mchedlidze, Gvantsa

19 October 2018

No description available.

530

Physik (PPN621336750)

Top Quark

W boson Polarisation

Anomalous Couplings

ATLAS Experiment

LHC

Search for Dark Matter Produced in pp Collisions with the ATLAS Detector

MacDonell, Danika

18 July 2022

Longstanding evidence from observational astronomy indicates that non-luminous "dark matter" constitutes the majority of all matter in the universe, yet this mysterious form of matter continues to elude experimental detection. This dissertation presents a search for dark matter at the Large Hadron Collider using 139 fb\(^{-1}\) of proton-proton collision data at a centre-of-mass energy of \(\sqrt{s} = 13\,\)TeV, recorded with the ATLAS detector from 2015 to 2018. The search targets a final state topology in which dark matter is produced from the proton-proton collisions in association with a pair of W bosons, one of which decays to a pair of quarks and the other to a lepton-neutrino pair. The dark matter is expected to pass invisibly through the detector, resulting in an imbalance of momentum in the plane transverse to the beam line. The search is optimized to test the Dark Higgs model, which predicts a signature of dark matter production in association with the emission of a hypothesized new particle referred to as the Dark Higgs boson. The Dark Higgs boson is predicted to decay to a W boson pair via a small mixing with the Standard Model Higgs boson discovered in 2012. Collisions that exhibit the targeted final state topology are selected for the search, and an approximate mass of the hypothetical Dark Higgs boson is reconstructed from the particles in each collision. A search is performed by looking for a deviation between distributions of the reconstructed Dark Higgs boson masses and Standard Model predictions for the selected collisions. The data is found to be consistent with the Standard Model prediction, and the results are used to constrain the parameters of the Dark Higgs model. This search complements and extends the reach of existing searches for the Dark Higgs model by the ATLAS and CMS collaborations. / Graduate

ATLAS Experiment

Dark Matter

Large Hadron Collider

Particle Physics

Monte Carlo

Dark Higgs

Proton-Proton Collisions

Energy Reconstruction and high-speed Data Transmission with FPGAs for the Upgrade of the ATLAS Liquid Argon Calorimeter at LHC

Stärz, Steffen

08 July 2015

The Liquid Argon calorimeter of the ATLAS detector at CERN near Geneva is equipped with improved readout and trigger electronics for the operation at higher luminosity LHC in the frame of several upgrades (Phase-0, I, and II). Special attention is given to an early digitisation of detector raw data and their following digital data transmission and processing via FPGAs already for the Level-1 trigger. The upgrades additionally foresee to provide higher spatial granularity information for the Level-1 trigger in order to improve its performance for low momentum single particles at increased collision rates. The first part of this dissertation contains the development and implementation of a modular detector simulation framework, AREUS, which allows to analyse different filter algorithms for the energy reconstruction as well as their performance with respect to the expected digitised detector raw data. In this detector simulation framework the detailed algorithmic functionality of the FPGAs has been taken into account. Various filter algorithms, especially the Optimal Filter and a Wiener Filter with Forward Correction, are discussed with regard to their performance in energy reconstruction of the future Liquid Argon calorimeter trigger system. In the second part of this thesis, the high-speed data transfer for the acquisition of the trigger data is being developed. For this purpose, a generic 10 Gigabit Ethernet UDP stack is designed in VHDL, that is currently applied in an ALTERA® Stratix-IV FPGA as part of the readout electronics of a demonstrator setup in the context of the Phase-0 Upgrade. After implementation in a prototype electronics board, data transfer from the detector front-end is realised. A successful test in the demonstrator setup installed in the ATLAS detector verifying the correct transmission of the Liquid Argon calorimeter trigger signals concludes this work. / Das Flüssig-Argon-Kalorimeter des ATLAS-Detektors am CERN bei Genf wird für den Betrieb am LHC mit erhöhter Luminosität im Rahmen mehrerer Upgrades (Phase-0, I und II) mit verbesserter Auslese- und Triggerelektronik ausgestattet. Ein besonderes Augenmerk liegt hierbei auf der frühzeitigen Digitalisierung der Detektorrohdaten und deren folgende digitale Übertragung sowie Verarbeitung mittels FPGAs bereits für den Level-1 Trigger. Die Upgrades sehen zusätzlich vor, dem Level-1 Trigger eine höhere Ortsauflösung bereitzustellen um seine Leistungsfähigkeit der Energierekonstruktion von niedrigenergetischen Teilchen bei erhöhter Kollisionsrate zu verbessern. Der erste Teil dieser Dissertation beinhaltet die Entwicklung und Umsetzung einer modularen Detektorsimulationsumgebung, AREUS, mit der verschiedene Filteralgorithmen zur Energierekonstruktion sowie deren Performanz in Abhängigkeit der erwarteten digitalisierten Detektorrohdaten analysiert werden können. Dabei wurde in der Simulationsumgebung die Funktionalität der Rechenarithmetik der später verwendeten FPGAs berücksichtigt. Verschiedener Filteralgorithmen, im Besonderen der Optimal Filter und ein Wiener Filter mit Korrekturglied, werden im Hinblick auf ihre Performanz der Energierekonstruktion für das zukünftige Triggersystem des Flüssig-Argon-Kalorimeters diskutiert. Der zweite Teil dieser Arbeit beschäftigt sich mit der Hochgeschwindigkeitsdatenübertragung zur Erfassung von Triggerdaten. Zu diesem Zweck wird ein generischer 10 Gigabit Ethernet UDP Stack in VHDL entworfen, der als Teil der Ausleseelektronik eines Demonstrator-Testaufbaus im Rahmen des Phase-0 Upgrades in einem ALTERA® Stratix-IV FPGA aktuell zum Einsatz kommt. Nach Implementierung in einem Prototypen einer Auslesekarte konnte ein Transfer von Detektordaten realisiert werden. Eine Überprüfung am Demonstrator-Testaufbau, welcher im ATLAS Detektor installiert ist, schließt diese Dissertation ab. Sie hat eine korrekte Übertragung von Triggersignalen des Flüssig-Argon-Kalorimeters erfolgreich bestätitgt.

CERN

LHC

ATLAS Experiment

Flüssig-Argon-Kalorimeter

Ausleseelektronik

Phase-I Upgrade

Filter

FPGA

Simulation

CERN

LHC

ATLAS Experiment

Liquid Argon Calorimeter

Readout Electronics

Phase-I Upgrade

Filter

FPGA

Simulation

ddc:530

rvk:VG 7107

Vector Boson Scattering and Electroweak Production of Two Like-Charge W Bosons and Two Jets at the Current and Future ATLAS Detector

Schnoor, Ulrike

30 January 2015

The scattering of electroweak gauge bosons is closely connected to the electroweak gauge symmetry and its spontaneous breaking through the Brout-Englert-Higgs mechanism. Since it contains triple and quartic gauge boson vertices, the measurement of this scattering process allows to probe the self-interactions of weak bosons. The contribution of the Higgs boson to the weak boson scattering amplitude ensures unitarity of the scattering matrix. Therefore, the scattering of massive electroweak gauge bosons is sensitive to deviations from the Standard Model prescription of the electroweak interaction and of the properties of the Higgs boson. At the Large Hadron Collider (LHC), the scattering of massive electroweak gauge bosons is accessible through the measurement of purely electroweak production of two jets and two gauge bosons. No such process has been observed before. Being the channel with the least amount of background from QCD-mediated production of the same final state, the most promising channel for the first measurement of a process containing massive electroweak gauge boson scattering is the one with two like-charge W bosons and two jets in the final state. This thesis presents the first measurement of electroweak production of two jets and two identically charged W bosons, which yields the first observation of a process with contributions from quartic gauge interactions of massive electroweak gauge bosons. An overview of the most important issues in Monte Carlo simulation of vector boson scattering processes with current Monte Carlo generators is given in this work. The measurement of the final state of two jets and two leptonically decaying same-charge W bosons is conducted based on proton-proton collision data with a center-of-mass energy of √s = 8 TeV, taken in 2012 with the ATLAS experiment at the LHC. The cross section of electroweak production of two jets and two like-charge W bosons is measured with a significance of 3.6 standard deviations to be σ(W± W±jj−EW[fiducial]) = 1.3 ± 0.4(stat.) ± 0.2(syst.) fb in a fiducial phase space region selected to enhance the contribution from W W scattering. The measurement is compatible with the Standard Model prediction of σ(W±W± jj−EW[fiducial]) = 0.95 ± 0.06 fb. Based on this measurement, limits on anomalous quartic gauge couplings are derived. The effect of anomalous quartic gauge couplings is simulated within the framework of an effective chiral Lagrangian unitarized with the K-matrix method. The limits for the anomalous coupling parameters α4 and α5 are found to be −0.14 < α4 < 0.16 and −0.23 < α5 < 0.24 at 95 % confidence level. Furthermore, the prospects for the measurement of the electroweak production of two same-charge W bosons and two jets within the Standard Model and with additional doubly charged resonances after the upgrade of the ATLAS detector and the LHC are investigated. For a high-luminosity LHC with a center-of-mass energy of √s = 14 TeV, the significance of the measurement with an integrated luminosity of 3000 fb^−1 is estimated to be 18.7 standard deviations. It can be improved by 30 % by extending the inner tracking detector of the atlas experiment up to an absolute pseudorapidity of |η| = 4.0.

info:eu-repo/classification/ddc/530

ddc:530

Elementarteilchenphysik; LHC

Energy Reconstruction and high-speed Data Transmission with FPGAs for the Upgrade of the ATLAS Liquid Argon Calorimeter at LHC

Stärz, Steffen

19 May 2015

The Liquid Argon calorimeter of the ATLAS detector at CERN near Geneva is equipped with improved readout and trigger electronics for the operation at higher luminosity LHC in the frame of several upgrades (Phase-0, I, and II). Special attention is given to an early digitisation of detector raw data and their following digital data transmission and processing via FPGAs already for the Level-1 trigger. The upgrades additionally foresee to provide higher spatial granularity information for the Level-1 trigger in order to improve its performance for low momentum single particles at increased collision rates. The first part of this dissertation contains the development and implementation of a modular detector simulation framework, AREUS, which allows to analyse different filter algorithms for the energy reconstruction as well as their performance with respect to the expected digitised detector raw data. In this detector simulation framework the detailed algorithmic functionality of the FPGAs has been taken into account. Various filter algorithms, especially the Optimal Filter and a Wiener Filter with Forward Correction, are discussed with regard to their performance in energy reconstruction of the future Liquid Argon calorimeter trigger system. In the second part of this thesis, the high-speed data transfer for the acquisition of the trigger data is being developed. For this purpose, a generic 10 Gigabit Ethernet UDP stack is designed in VHDL, that is currently applied in an ALTERA® Stratix-IV FPGA as part of the readout electronics of a demonstrator setup in the context of the Phase-0 Upgrade. After implementation in a prototype electronics board, data transfer from the detector front-end is realised. A successful test in the demonstrator setup installed in the ATLAS detector verifying the correct transmission of the Liquid Argon calorimeter trigger signals concludes this work. / Das Flüssig-Argon-Kalorimeter des ATLAS-Detektors am CERN bei Genf wird für den Betrieb am LHC mit erhöhter Luminosität im Rahmen mehrerer Upgrades (Phase-0, I und II) mit verbesserter Auslese- und Triggerelektronik ausgestattet. Ein besonderes Augenmerk liegt hierbei auf der frühzeitigen Digitalisierung der Detektorrohdaten und deren folgende digitale Übertragung sowie Verarbeitung mittels FPGAs bereits für den Level-1 Trigger. Die Upgrades sehen zusätzlich vor, dem Level-1 Trigger eine höhere Ortsauflösung bereitzustellen um seine Leistungsfähigkeit der Energierekonstruktion von niedrigenergetischen Teilchen bei erhöhter Kollisionsrate zu verbessern. Der erste Teil dieser Dissertation beinhaltet die Entwicklung und Umsetzung einer modularen Detektorsimulationsumgebung, AREUS, mit der verschiedene Filteralgorithmen zur Energierekonstruktion sowie deren Performanz in Abhängigkeit der erwarteten digitalisierten Detektorrohdaten analysiert werden können. Dabei wurde in der Simulationsumgebung die Funktionalität der Rechenarithmetik der später verwendeten FPGAs berücksichtigt. Verschiedener Filteralgorithmen, im Besonderen der Optimal Filter und ein Wiener Filter mit Korrekturglied, werden im Hinblick auf ihre Performanz der Energierekonstruktion für das zukünftige Triggersystem des Flüssig-Argon-Kalorimeters diskutiert. Der zweite Teil dieser Arbeit beschäftigt sich mit der Hochgeschwindigkeitsdatenübertragung zur Erfassung von Triggerdaten. Zu diesem Zweck wird ein generischer 10 Gigabit Ethernet UDP Stack in VHDL entworfen, der als Teil der Ausleseelektronik eines Demonstrator-Testaufbaus im Rahmen des Phase-0 Upgrades in einem ALTERA® Stratix-IV FPGA aktuell zum Einsatz kommt. Nach Implementierung in einem Prototypen einer Auslesekarte konnte ein Transfer von Detektordaten realisiert werden. Eine Überprüfung am Demonstrator-Testaufbau, welcher im ATLAS Detektor installiert ist, schließt diese Dissertation ab. Sie hat eine korrekte Übertragung von Triggersignalen des Flüssig-Argon-Kalorimeters erfolgreich bestätitgt.

info:eu-repo/classification/ddc/530

ddc:530

Leaving No Matter Unturned / Analysing existing LHC measurements and events with jets and missing transverse energy measured by the ATLAS Experiment in search of Dark Matter

Habedank, Martin

25 March 2024

Diverse astrophysikalische Beobachtungen weisen auf bislang unerklärte Materie hin, die hauptsächlich gravitativ interagiert. Wenn diese Materie, bezeichnet als Dunkle Materie, ein Elementarteilchen ist, könnte sie in Teilchenkollisionen am Large Hadron Collider produziert werden. Aufgrund ihrer schwachen Wechselwirkung mit normaler Materie könnte sie jedoch nicht direkt mit den Vielzweckdetektoren am Large Hadron Collider beobachtet werden. Ihre Produktion würde sich stattdessen in Ereignissen zeigen, in denen ein Rückstoß von Detektor-sichtbaren Objekten gegen die Detektor-unsichtbare Dunkle Materie besteht, was fehlende transversale Energie verursacht. Diese Dissertation beschäftigt sich mit Endzuständen, in denen diese sichtbaren Objekte sogenannte Jets sind. In dieser Dissertation wird eine Messung des Endzustands aus großer fehlender transversaler Energie und mindestens einem Jet in 139/fb an Proton–Proton-Kollisionen bei 13 TeV, aufgezeichnet mit dem ATLAS-Detektor am Large Hadron Collider, durchgeführt. Zwischen den gemessenen Daten und der Standard-Modell-Vorhersage wird in einer statistischen Optimierung gute Übereinstimmung gefunden. Die Messung wird von Detektor-Effekten bereinigt, um spätere Reinterpretation zu vereinfachen. Messungen, die auf diese Art aufbereitet wurden, können beispielsweise von der Contur-Software benutzt werden, um Parametergrenzen für neue Theorien festzustellen. Sowohl die Ergebnisse der Messung, als auch die Contur-Software, welche auf existierende Messungen am Large Hadron Collider zurückgreift, werden verwendet, um Ausschlussgrenzen für ein Modell, das Dunkle Materie erklären kann, festzustellen. Betrachtet wird das Modell von zwei Higgs-Dubletts und einem pseudoskalaren Botenteilchen zu Dunkler Materie. / Various astrophysical observations point towards an as-of-yet unexplained, mainly gravitationally interacting type of matter. If this matter, called Dark Matter, is an elementary particle, it could be produced in particle collisions at the Large Hadron Collider. Given its weak interaction with ordinary matter, however, it would not be directly observable with the general-purpose detectors at the Large Hadron Collider. Its production would therefore manifest as events in which detector-visible objects recoil against the detector-invisible Dark Matter, giving rise to missing transverse energy. This thesis focuses on final states in which these visible objects are jets. A measurement of the final state of large missing transverse energy and at least one jet in 139/fb of proton–proton collisions at 13 TeV recorded with the ATLAS detector at the Large Hadron Collider is performed in this thesis. Good agreement between measured data and Standard-Model prediction is found in a statistical fit. The measurement is corrected for detector effects to facilitate later reinterpretation. Measurements prepared in such a way can, for example, be exploited by the Contur toolkit to set constraints on new theories. Both, the results of the measurement and the Contur toolkit making use of existing measurements at the Large Hadron Collider, are employed to set exclusion limits on a model able to explain Dark Matter, the two-Higgs-doublet model with a pseudoscalar mediator to Dark Matter.

Dunkle Materie

LHC

ATLAS-Experiment

fehlende transversale Energie

Jets

2HDM+a

Contur

Messung

Suche

Unfolding

Dark Matter

LHC

ATLAS Experiment

missing transverse energy

jets

2HDM+a

Contur

measurement

search

unfolding

539 Moderne Physik

ddc:539