The ATLAS Experiment and the CERN Large Hadron Collider

Similar documents
The ATLAS Experiment and the CERN Large Hadron Collider. HEP101-6 March 12, 2012

The ATLAS Experiment and the CERN Large Hadron Collider

The ATLAS Experiment and the CERN Large Hadron Collider

Part II: Detectors. Peter Schleper Universität Hamburg

Physics at Hadron Colliders

Invariant Mass, Missing Mass, jet reconstruction and jet flavour tagging

Homework 3: Group Theory and the Quark Model Due February 16

ATLAS-CONF October 15, 2010

Particles and Deep Inelastic Scattering

The Collider Detector at Fermilab. Amitabh Lath Rutgers University July 25, 2002

Optimizing Selection and Sensitivity Results for VV->lvqq, 6.5 pb -1, 13 TeV Data

Particle Physics Lecture 1 : Introduction Fall 2015 Seon-Hee Seo

A brief history of accelerators, detectors and experiments: (See Chapter 14 and Appendix H in Rolnick.)

La ricerca dell Higgs Standard Model a CDF

Modern Accelerators for High Energy Physics

The Particle World. This talk: What is our Universe made of? Where does it come from? Why does it behave the way it does?

Tau Lepton Reconstruction in ATLAS. Tau 2016 Conference, Beijing, 21st September 2016

Reconstruction in Collider Experiments (Part IX)

The achievements of the CERN proton antiproton collider

Physics Quarknet/Service Learning

Particle Physics: Problem Sheet 5

The Discovery of the Higgs Boson: one step closer to understanding the beginning of the Universe

Experimental Particle Physics Informal Lecture & Seminar Series Lecture 1 Detectors Overview

Particle Detectors. How to See the Invisible

Fall Quarter 2010 UCSB Physics 225A & UCSD Physics 214 Homework 1

Highlights of top quark measurements in hadronic final states at ATLAS

MASS OF THE TOP QUARK

Tutorial on Top-Quark Physics

2 ATLAS operations and data taking

Reconstruction and identification of hadronic τ decays with ATLAS

Elementary Particle Physics Glossary. Course organiser: Dr Marcella Bona February 9, 2016

Standard Model of Particle Physics SS 2013

Relativistic Kinematics Cont d

The God particle at last? Science Week, Nov 15 th, 2012

PG lectures- Particle Physics Introduction. C.Lazzeroni

Results from the Tevatron: Standard Model Measurements and Searches for the Higgs. Ashutosh Kotwal Duke University

Introduction to CERN and CMS

LHC Detectors and their Physics Potential. Nick Ellis PH Department, CERN, Geneva

The Large Hadron Collider, and New Avenues in Elementary Particle Physics. Gerard t Hooft, Public Lecture, IPMU Tokyo, April 16, 2015

Lecture 2 & 3. Particles going through matter. Collider Detectors. PDG chapter 27 Kleinknecht chapters: PDG chapter 28 Kleinknecht chapters:

Discovery of the W and Z 0 Bosons

Physics with Tau Lepton Final States in ATLAS. Felix Friedrich on behalf of the ATLAS Collaboration

CDF top quark " $ )(! # % & '

LHC & ATLAS. The largest particle physics experiment in the world. Vincent Hedberg - Lund University 1

Neutrino Physics. Kam-Biu Luk. Tsinghua University and University of California, Berkeley and Lawrence Berkeley National Laboratory

MINERVA Masterclass. Teachers Manual. Vera Zimanyine Horvath Francesco Mezzanotte Tom Lambert

(a) (b) Fig. 1 - The LEP/LHC tunnel map and (b) the CERN accelerator system.

Nuclear and Particle Physics 3: Particle Physics. Lecture 1: Introduction to Particle Physics February 5th 2007

Problem Set # 2 SOLUTIONS

The God particle at last? Astronomy Ireland, Oct 8 th, 2012

Part II Particle and Nuclear Physics Examples Sheet 1

Top Physics in Hadron Collisions

Electroweak Physics. Krishna S. Kumar. University of Massachusetts, Amherst

How and Why to go Beyond the Discovery of the Higgs Boson

Particle detection 1

EP228 Particle Physics

Analysis of Top Quarks Using a Kinematic Likelihood Method

Accelerators and Colliders

Calorimetry in particle physics experiments

Results on top physics by CMS

Recent CMS results on heavy quarks and hadrons. Alice Bean Univ. of Kansas for the CMS Collaboration

Triggering on Long-lived neutral particles in ATLAS

How and Why to go Beyond the Discovery of the Higgs Boson

The ATLAS Detector - Inside Out Julia I. Hofmann

Theory English (Official)

Performance of muon and tau identification at ATLAS

VBF SM Higgs boson searches with ATLAS

Studies on hadronic top decays

Search for WZ lνbb at CDF: Proving ground of the Hunt for the

Excited Electron Search in the e eeγ Channel in ATLAS at S = 7 TeV

Appendix A2. Particle Accelerators and Detectors The Large Hadron Collider (LHC) in Geneva, Switzerland on the Border of France.

The Physics of Particles and Forces David Wilson

LHC State of the Art and News

Modern physics 1 Chapter 13

Future prospects for the measurement of direct photons at the LHC

14 Top Quark. Completing the Third Generation

Standard Model physics with taus in ATLAS

Standard Model of Particle Physics SS 2012

Decay rates and Cross section. Ashfaq Ahmad National Centre for Physics

Particle Physics I Lecture Exam Question Sheet

Elementary particles and typical scales in high energy physics

Option 212: UNIT 2 Elementary Particles

Search for a Z at an e + e - Collider Thomas Walker

Muon reconstruction performance in ATLAS at Run-2

Evidence for Single Top Quark Production. Reinhard Schwienhorst

Background Analysis Columbia University REU 2015

Determination of Electroweak Parameters

Overview. The quest of Particle Physics research is to understand the fundamental particles of nature and their interactions.

A Search for the Higgs

V0 cross-section measurement at LHCb. RIVET analysis module for Z boson decay to di-electron

IX. Electroweak unification

Physics 4213/5213 Lecture 1

Standard Model of Particle Physics SS 2013

Higgs Searches at CMS

Dissecting the Higgs Discovery: The Anatomy of a 21st Century Scientific Achievement

Conference Report Mailing address: CMS CERN, CH-1211 GENEVA 23, Switzerland

Particle Physics. All science is either physics or stamp collecting and this from a 1908 Nobel laureate in Chemistry

Particles and Universe: Particle detectors

ATLAS Z-Path Masterclass 2013

2007 Section A of examination problems on Nuclei and Particles

Transcription:

The ATLAS Experiment and the CERN Large Hadron Collider HEP101-4 February 20, 2012 Al Goshaw 1

HEP 101 Today Introduction to HEP units Particles created in high energy collisions What can be measured in the ATLAS detector? Basics of relativistic mechanics Measuring particle properties with the application of relativistic mechanics See the HEP101 web site for lectures and other information about the Duke LHC research groups: http://web.phy.duke.edu/~goshaw/hep101_2012/ 2

HEP units of measurement As in any branch of science, the first barrier to carrying out quantitative calculations is to understand the units being used. We use the Standard International system of units, but scale them to be more convenient for the description of elementary particles and their interactions. Length 1 fermi (fm) = 10-15 m ( the size of a proton is ~ 1 fm) Area 1 barn (b) = 10-28 m 2 ( typical cross sections are in mb, µb, nb, pb) Energy 1 ev = 1.60x10-19 J ( typical energies MeV, GeV, TeV) Mass Mc 2 in GeV (shorthand M in GeV/c 2 ) For a proton Mc 2 ~ 1.0 GeV. For an electron Mc 2 ~ 0.5 MeV. Momentum Pc in GeV (shorthand p in GeV/c) 3

HEP units of measurement Some handy conversion factors c = 3.00 x 10 23 fm/s h = 6.58 x 10-25 GeV s h c = 0.197 GeV fm (h c) 2 = 0.389 GeV 2 mb All these units are SI-based as they ultimately refer to the the standards of length, mass and time to be the meter, kilogram and second. 4

Particles created in high energy collisions Some elementary particles are stable and do not decay: protons and the anti-matter partner anti-protons electrons and the anti-matter partner positrons neutrinos photons Others are unstable but decay with long lifetimes: neutrons decay to p + e - + ν e muons decay to e - + ν e + ν µ pions decay to µ - + ν µ These are so long-lived that they travel many meters before decaying and can be observed directly in particle detectors. 5

Particles created in high energy collisions Many important elementary particles decay so quickly that they do not travel distances that are measurable by particle detectors: The weak force carriers. Example decays are: Z -> µ + + µ - W -> µ + + ν µ The top quark: t -> W + + b quark The Higgs boson (decay modes depend on its mass): H -> W + + W + if high mass H -> b + b or two photons if low mass (now favored) 6

Particles created in high energy collisions What can be measured for stable and long-lived particles? 1. The particle s momentum from the curvature in in a known magnetic field. Use the detailed particle path measured in the tracking detectors that were described last lecture. 2. The particle s energy using the total energy deposit in the calorimeters described last lecture. 3. The particle type and therefore mass using the signature left in the tracking/calorimeter/muon detectors. The properties of very short lived particles can be measured from their decay products as discussed below. 7

Measuring stable and long-lived particles measure the momentum of protons, electrons, muons, charged pions, measure the energy of neutral particles ( photons, neutrons, ) in calorimeters identify the type of particle by how it interacts with detector components 8 8

Studying short-lived particles For very short lived particles only the stable decay products are detected: Z and W bosons, top quarks, excited states of protons, Higgs bosons, Z -> µ + µ - W -> e ν top -> W b -> e ν b 9

Z boson production with decay to µ + µ - 10

Z boson production with decay to e + e - 11

W boson production with decay to e + ν 12

Et=37 GeV e e γ Et=30 GeV γ e Et=51 GeV M(e,e) =91.2 GeV e e γ e Graduate Seminar September 2009 13 13 13

A top pair production candidate One W decays to an electron, the other to a muon Event display of an top pair e-mu dilepton candidate with two b-tagged jets. The electron is shown by the red track pointing to the green calorimeter cluster in the 3D view, and the muon by the long red track intersecting the muon chambers. The two b-tagged jets are shown by the purple cones, whose sizes are proportional to the jet energies. 14 Tom LeCompte, ANL 14

A lead-lead nuclear collision 15

γ e + e - conversions 2009 data p T (e + ) = 1.75 GeV, 11 TRT high-threshold hits p T (e - ) = 0.79 GeV, 3 TRT high-threshold hits e + e- γ conversion point R ~ 30 cm (1 st Silicon strip layer) 16 16

Relativistic Kinematics 17

Single Particle Kinematics Consider the motion of a point particle in an inertial reference frame. m = particle s rest mass v = d r /dt t and r measured by clocks and meter sticks at rest in O τ = time measured by a clock carried by m x O y r(t) m v(t) z Define β = v /c and γ = 1/ 1 - β 2 Then: p = γ β mc E = γ mc 2 = K + mc 2 Also t = γ τ (time dialation) For any free particle note that E 2 = (pc) 2 + (mc 2 ) 2 18

Four vectors The location of a particle can be specified by a four component vector X µ = ( ct, x, y, z ) = (ct, r ) where µ is an index 0,1,2,3 specifying the vector component. Other examples of 4-vectors are: 4-velocity U µ = d X µ /d τ = γ ( c, v ) 4-momentum P µ = m U µ = m γ ( c, v ) = (E/c, p ) 4-force F µ = d P µ /d τ = ( γ/c de/dt, γ d p /dt ) 19

Algebra of four vectors Some notation: contravariant 4-vector V µ = (v o, +v ) covariant 4-vector V µ = (v o, -v ) Define a scalar product: V 2 = V V = V µ V µ = V µ V µ = v o 2 - v 2 ( the sum over repeated indices is implied) Some examples: P 2 = (E/c) 2 - p 2 = (mc) 2 U 2 = γ 2 c 2 - γ 2 v 2 = c 2 It is convenient to introduce a metric tensor: V µ = g µν V ν V 2 = V µ g µν V ν g µν = g µν = +1 0 0 0 0-1 0 0 0 0-1 0 0 0 0-1 20

Lorentz transformations The kinematic quantities describing a point particle can be transformed between inertial reference frames. A simple example is a boost along one axis (say the z axis). Let β o = v o /c and γ o = 1/ 1 - β o 2 Any 4-vector V in O has a value V when measured in O. V µ = L µ ν Vν where the L µ ν are the elements of a boost matrix R b. R b = γ o 0 0 -β o γ ο 0 1 0 0 0 0 1 0 -β o γ o 0 0 γ o 21

Lorentz transformations For example find the momentum and energy of this particle when measured in the reference frame O p,e m Use the boost matrix R b as given on the previous page: P µ = L µ ν Pν p x = p x p y = p y p z = γ o (p z - β o E/c ) E /c = γ o (E/c - β o p z ) 22

Applications of relativisitic kinematics Calculate a particle s mass from its decay products: M -> m 1 + m 2 Measure energy and momentum of m 1 and m 2 and then calculate the mass of M. To fix these ideas work 3 homework problems (given in the lecture). END LECTURE 4 23

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback