Magnetic field simulation and mapping for the Qweak experiment

Wang, Peiqing

07 June 2007

The Qweak experiment at Thomas Jefferson National Accelerator Facility (Jefferson Lab) will measure the proton's weak charge by measuring the parity violating asymmetry in elastic electron-proton scattering at very low momentum transfer, with the aim of determining the proton's weak charge with 4% combined statistical and systematic errors. The experimental apparatus includes a longitudinally polarized electron beam, a liquid hydrogen target, a room temperature toroidal magnetic spectrometer, and a set of precision detectors for the scattered electrons. The toroidal magnetic spectrometer, which will deflect away the inelastic scattered electrons and focus the elastic scattered electrons onto the detectors, plays a crucially important role in the experiment. In this thesis, in order to meet the requirements for the installation and calibration of the toroidal magnetic spectrometer, the numerical simulation of the spectrometer's magnetic field based on a realistic magnet model is discussed, a precise 3D field mapping is introduced, and some simulation results are provided. The zero-crossing analysis technique, which can be used to precisely infer the individual coil locations of the toroidal magnet, is presented and explored in detail. / October 2007

parity violation

scattering

weak charge

weak mixing angle

toroidal

magnetic field

mapping

zero-crossing

Magnetic field simulation and mapping for the Qweak experiment

Wang, Peiqing

07 June 2007

The Qweak experiment at Thomas Jefferson National Accelerator Facility (Jefferson Lab) will measure the proton's weak charge by measuring the parity violating asymmetry in elastic electron-proton scattering at very low momentum transfer, with the aim of determining the proton's weak charge with 4% combined statistical and systematic errors. The experimental apparatus includes a longitudinally polarized electron beam, a liquid hydrogen target, a room temperature toroidal magnetic spectrometer, and a set of precision detectors for the scattered electrons. The toroidal magnetic spectrometer, which will deflect away the inelastic scattered electrons and focus the elastic scattered electrons onto the detectors, plays a crucially important role in the experiment. In this thesis, in order to meet the requirements for the installation and calibration of the toroidal magnetic spectrometer, the numerical simulation of the spectrometer's magnetic field based on a realistic magnet model is discussed, a precise 3D field mapping is introduced, and some simulation results are provided. The zero-crossing analysis technique, which can be used to precisely infer the individual coil locations of the toroidal magnet, is presented and explored in detail.

parity violation

scattering

weak charge

weak mixing angle

toroidal

magnetic field

mapping

zero-crossing

Magnetic field simulation and mapping for the Qweak experiment

Wang, Peiqing

07 June 2007

The Qweak experiment at Thomas Jefferson National Accelerator Facility (Jefferson Lab) will measure the proton's weak charge by measuring the parity violating asymmetry in elastic electron-proton scattering at very low momentum transfer, with the aim of determining the proton's weak charge with 4% combined statistical and systematic errors. The experimental apparatus includes a longitudinally polarized electron beam, a liquid hydrogen target, a room temperature toroidal magnetic spectrometer, and a set of precision detectors for the scattered electrons. The toroidal magnetic spectrometer, which will deflect away the inelastic scattered electrons and focus the elastic scattered electrons onto the detectors, plays a crucially important role in the experiment. In this thesis, in order to meet the requirements for the installation and calibration of the toroidal magnetic spectrometer, the numerical simulation of the spectrometer's magnetic field based on a realistic magnet model is discussed, a precise 3D field mapping is introduced, and some simulation results are provided. The zero-crossing analysis technique, which can be used to precisely infer the individual coil locations of the toroidal magnet, is presented and explored in detail.

parity violation

scattering

weak charge

weak mixing angle

toroidal

magnetic field

mapping

zero-crossing

Measurement of neutral current Drell-Yan production at 8 TeV with the ATLAS detector

Kwan, Tony

16 August 2017

Neutral current Drell-Yan production in proton-proton collisions at the LHC was studied with the ATLAS detector. The 20.1 inverse femtobarn data set used in this precision measurement was collected in 2012 during which the LHC collided protons at a centre-of-mass energy of 8 TeV. The production rate or differential cross-section was measured in three-dimensions: invariant mass, absolute rapidity, and cosine of the polar angle in the Collins-Soper frame. A measurement of the forward-backward asymmetry was obtained from the differential cross-section by summing over the forward and the backward events and taking their difference. The three-dimensional differential cross-section measurement presented in this dissertation can be used to constrain the invariant mass- and rapidity-dependent parton distribution functions of the proton and the forward-backward asymmetry results can be used to extract a measurement of the weak mixing angle. / Graduate

Experimental particle physics

CERN

LHC

ATLAS

Standard Model

Drell-Yan

Parton distribution functions

Weak mixing angle

Determination of the Weak Charge of the Proton Through Parity Violating Asymmetry Measurements in the Elastic EP Scattering

Subedi, Adesh

13 December 2014

The Qweak experiment has taken data to make a 2.5 percent measurement of parity violating elastic ep asymmetry in the four momentum transfer region of 0.0250 (GeV/c)2. This asymmetry is proportional to the weak charge of the proton, which is related to the weak mixing angle, sin2(thetaW). The final Qweak measurement will provide the most precise measurement of the weak mixing angle below the Z° pole to test the Standard Model prediction. A description of the experimental apparatus is provided in this dissertation. The experiment was carried out using a longitudinally polarized electron beam of up to 180 microampere on a 34.5 cm long unpolarized liquid hydrogen target. The Qweak target is not only the world’s highest cryogenic target ever built for a parity experiment but also is the least noisy target. This dissertation provides a detailed description of this target and presents a thorough analysis of the target performance. Statistical analysis of Run 1 data, collected between Feb - May 2011, is done to extract a blinded parity violating asymmetry of size--299.7 +/- 13.4 (stat.) +/- 17.2 (syst.) +/- 68 (blinding) parts-per-billion. This resulted in a preliminary proton’s weak charge of value 0.0865 +/- 0.0085, a 9% measurement. Based on this blinded asymmetry, the weak mixing angle was determined to be sin2(thetaW) = 0.23429 +/- 0.00211.

weak mixing angle

standard model test

elastic asymmetry

highest power cryogenic target

parity violation

A Measurement of the Proton's Weak Charge Using an Integration Cerenkov Detector System

Wang, Peiqing

02 September 2011

The Q-weak experiment at Thomas Jefferson National Accelerator Facility (USA) will make a precision determination of the proton weak charge with approximately 4% combined statistical and systematic uncertainties via a measurement of the parity violating asymmetry in elastic electron-proton scattering at very low momentum transfer and forward angle. This will allow an extraction of the weak mixing angle at Q^2=0.026 (GeV/c)^2 to approximately 0.3%. The weak mixing angle is a fundamental parameter in the Standard Model of electroweak interactions. At the proposed accuracy, a measured deviation of this parameter from the predicted value would indicate new physics beyond what is currently described in the Standard Model. Without deviation from the predicted value, this measurement would place stringent limits on possible extensions to the Standard Model and constitute the most precise measurement of the proton's weak charge to date. The key experimental apparatus include a liquid hydrogen target, a toroidal magnetic spectrometer and a set of eight Cerenkov detectors. The Cerenkov detectors form the main detector system for the Q-weak experiment and are used to measure the parity violating asymmetry during the primary Q-weak production runs. The Cerenkov detectors form the main subject of this thesis. Following a brief introduction to the experiment, the design, development, construction, installation, and testing of this detector system will be discussed in detail. This is followed by a detailed discussion of detector diagnostic data analysis and the corresponding detector performance. The experiment has been successfully constructed and commissioned, and is currently taking data. The thesis will conclude with a discussion of the preliminary analysis of a small portion of the liquid hydrogen data.

Standard Model

weak Interaction

weak mixing angle

weak charge

electron-proton scattering

parity violation

Cerenkov detector

Q-weak

momentum transfer

cross-section asymmetry

hadronic structure

form factor

Towards a Precision Measurement of Parity-Violating e-p Elastic Scattering at Low Momentum Transfer

Pan, Jie

27 July 2012

The goal of the Q-weak experiment is to make a measurement of the proton's weak charge ($Q^p_W = 1-4\sin^2\theta_W$) to an accuracy of ~4%. This would represent a ~0.3% determination of the weak mixing angle ($\sin^2\theta_W$) at low energy. The measurement may be used for a precision test of the Standard Model (SM) prediction on the running of $\sin^2\theta_W$ with energy scale. The Q-weak experiment operates at Thomas Jefferson National Accelerator Facility (Jefferson Lab). The experiment determines the proton's weak charge by measuring the parity violating asymmetry in elastic electron-proton scattering at low momentum transfer $Q^2 = 0.026 (GeV/c)^2$ and forward angles (~8 degree). The anticipated size of the asymmetry, based on the SM, is about 230 parts per billion (ppb). With the proposed accuracy, the experiment may probe new physics beyond Standard Model at the TeV scale. This thesis focuses on my contributions to the experiment, including track reconstruction for momentum transfer determination of the scattering process, and the focal plane scanner, a detector I designed and built to measure the flux profile of scattered electrons on the focal plane of the Q-weak spectrometer to assist in the extrapolation of low beam current tracking results to high beam current. Preliminary results from the commissioning and the first run period of the Q-weak experiment are reported and discussed.

Electroweak

Standard Model

Weak Charge

Weak Mixing Angle

Track Reconstruction

Momentum Transfer

e-p Scattering

Parity Violation

Scanner Detector

Flux Profile Image

Parity Violating Asymmetry

Cerenkov

A Measurement of the Proton's Weak Charge Using an Integration Cerenkov Detector System

Wang, Peiqing

02 September 2011

The Q-weak experiment at Thomas Jefferson National Accelerator Facility (USA) will make a precision determination of the proton weak charge with approximately 4% combined statistical and systematic uncertainties via a measurement of the parity violating asymmetry in elastic electron-proton scattering at very low momentum transfer and forward angle. This will allow an extraction of the weak mixing angle at Q^2=0.026 (GeV/c)^2 to approximately 0.3%. The weak mixing angle is a fundamental parameter in the Standard Model of electroweak interactions. At the proposed accuracy, a measured deviation of this parameter from the predicted value would indicate new physics beyond what is currently described in the Standard Model. Without deviation from the predicted value, this measurement would place stringent limits on possible extensions to the Standard Model and constitute the most precise measurement of the proton's weak charge to date. The key experimental apparatus include a liquid hydrogen target, a toroidal magnetic spectrometer and a set of eight Cerenkov detectors. The Cerenkov detectors form the main detector system for the Q-weak experiment and are used to measure the parity violating asymmetry during the primary Q-weak production runs. The Cerenkov detectors form the main subject of this thesis. Following a brief introduction to the experiment, the design, development, construction, installation, and testing of this detector system will be discussed in detail. This is followed by a detailed discussion of detector diagnostic data analysis and the corresponding detector performance. The experiment has been successfully constructed and commissioned, and is currently taking data. The thesis will conclude with a discussion of the preliminary analysis of a small portion of the liquid hydrogen data.

Standard Model

weak Interaction

weak mixing angle

weak charge

electron-proton scattering

parity violation

Cerenkov detector

Q-weak

momentum transfer

cross-section asymmetry

hadronic structure

form factor

Towards a Precision Measurement of Parity-Violating e-p Elastic Scattering at Low Momentum Transfer

Pan, Jie

27 July 2012

The goal of the Q-weak experiment is to make a measurement of the proton's weak charge ($Q^p_W = 1-4\sin^2\theta_W$) to an accuracy of ~4%. This would represent a ~0.3% determination of the weak mixing angle ($\sin^2\theta_W$) at low energy. The measurement may be used for a precision test of the Standard Model (SM) prediction on the running of $\sin^2\theta_W$ with energy scale. The Q-weak experiment operates at Thomas Jefferson National Accelerator Facility (Jefferson Lab). The experiment determines the proton's weak charge by measuring the parity violating asymmetry in elastic electron-proton scattering at low momentum transfer $Q^2 = 0.026 (GeV/c)^2$ and forward angles (~8 degree). The anticipated size of the asymmetry, based on the SM, is about 230 parts per billion (ppb). With the proposed accuracy, the experiment may probe new physics beyond Standard Model at the TeV scale. This thesis focuses on my contributions to the experiment, including track reconstruction for momentum transfer determination of the scattering process, and the focal plane scanner, a detector I designed and built to measure the flux profile of scattered electrons on the focal plane of the Q-weak spectrometer to assist in the extrapolation of low beam current tracking results to high beam current. Preliminary results from the commissioning and the first run period of the Q-weak experiment are reported and discussed.

Electroweak

Standard Model

Weak Charge

Weak Mixing Angle

Track Reconstruction

Momentum Transfer

e-p Scattering

Parity Violation

Scanner Detector

Flux Profile Image

Parity Violating Asymmetry

Cerenkov

Numerical evaluation of Mellin-Barnes integrals in Minkowskian regions and their application to two-loop bosonic electroweak contributions to the weak mixing angle of the Zbb(bar)-vertex

Usovitsch, Johann

24 October 2018

In der Z-Boson-Resonanzphysik sind mehrere Präzisionsobservablen in einem perfekten Zustand, bei dem die theoretische Unsicherheit niedriger ist als die gegenwärtige experimentelle Unsicherheit. Das Konzept für den zukünftigen Teilchenbeschleuniger Future Circular Collider (FCC), will eine Verbesserung der Messungen für die Präzisionsobservablen um ein bis zwei signifikante Stellen erreichen. Damit werden die Vorhersagen des elektroschwachen Standardmodells in eine Situation versetzt, in der vollständige Zweischleifenkorrekturen zusammen mit den führenden Dreischleifenkorrekturen obligatorisch werden. 2016 wurden die vollständigen Zweischleifenkorrekturen für den effektiven schwachen Mischungswinkel für die bottom Quarks sin^2/theta/^b_eff berechnet, indem die fehlenden bosonischen Zweischleifenkorrekturen bereitgestellt wurden. Dabei liegt die Schwierigkeit in der Berechnung der entsprechenden Zwei-Schleifen Vertex-Feynman-Integrale, die mehrere massive Teilchen einschließen. Gegenwärtig ist die analytische Rechnung der meisten dieser Integrale schwierig und deswegen werden rein numerische Techniken, mittels Sektorzerlegungsansatz und der Integralansatz nach Mellin-Barnes, angewandt. Es war bis vor kurzem nicht bekannt, wie Mellin-Barnes-Integraldarstellungen in den minkowskischen Integrationsgebieten numerisch behandelt werden können. Um dieses Problem anzugehen, stellen wir eine Vielzahl von ein- und mehrdimensionaler Techniken vor, die ein Teil des neuen Programms MBnumerics.m sind, welches in dieser Dissertation entwickelt wurde. Der Sektorzerlegungsansatz und der Integralansatz nach Mellin-Barnes sind zusammen ausreichend, um elektroschwache Zweischleifenkorrekturen für die Präzisionsobservablen der Annihilation von e^+e^- in zwei Fermionen in der Z-Bosonresonanz auszurechnen. Aktuell führt dies zu der genauesten Vorhersage für den effektiven elektroschwachen Mischungswinkel für bottom Quarks sin^2/theta/^b_eff = 0.232312. / In the Z-boson resonance physics several precision observables are in a perfect state, where the theory uncertainty is lower than the present experimental uncertainty. The ambitious concepts for the future collider, Future Circular Collider (FCC), aim for an improvement of measurements for the precision observables by one to two significant digits. This will put the Electroweak Standard Model predictions in a situation where complete two-loop corrections together with the leading three-loop corrections will become mandatory. The complete two-loop corrections for effective weak mixing angle for bottom quarks sin^2/theta/^b_eff were reported recently, by providing the missing bosonic two-loop corrections. The difficult task in this computation is the calculation of the corresponding two-loop vertex Feynman integrals which include several massive particles. At present the analytic evaluation for most of these integrals is out of reach and purely numerical techniques were applied. Only two methods, sector decomposition approach and the Mellin-Barnes integral approach, are known to extract infrared and ultraviolet singularities in a systematic way for a general Feynman integral with fully automatized algorithms. It was not known until recently how to treat Mellin-Barnes integral representations in Minkowskian regions numerically. To address this problem we introduce and discuss in detail a variety of one- and multi-dimensional techniques, which are part of a new program MBnumerics.m developed in this thesis work. Two techniques, sector decomposition and Mellin-Barnes integral approach, are together sufficient to treat electroweak two-loop corrections to the precision observables for the e^+e^- annihilation into two fermions at the Z-boson resonance. This leads to the most precise prediction at present for the effective weak mixing angle for bottom quarks: sin^2/theta/^b_eff=0.232312.

bosonische Korrekturen

Z-Boson-Resonanzphysik

Mehr-Schleifen-Rechnung

minkowskische Integrationsgebiete

Mellin-Barnes-Integrale

bosonic corrections

Z-boson resonance physics

multi-loop calculations

Mellin-Barnes integrals

Minkowskian regions

530 Physik

UO 5510

ddc:530