Einige interessante Aspekte der in der Zielsetzung genannten Fragestellungen. Appetithappen -> Antworten spaeter in der Vorlesung.
|
|
|
- Cecil Ross
- 6 years ago
- Views:
Transcription
1 0. Einführung Einige interessante Aspekte der in der Zielsetzung genannten Fragestellungen. Appetithappen -> Antworten spaeter in der Vorlesung. Folien auf Englisch (aus anderer Vorlesung ausgeliehen) -> sorry. Muendlich auf Deutsch. Weitere Teile der Vorlesung auf Deutsch A. Geiser, Was bedeutet Masse? 1
2 History of basic building blocks of matter motivation: find smallest possible number ΣΛ 0 + π + ο + pω + Κ π ο πκ 0 Κ + + Supersymmetry AD A. Geiser, Was bedeutet Masse? 2
3 The Mystery of Mass upu d down c charm s strange t top. ν e e-neutrino e electron. ν µ µ-neutrino µ muon. b bottom ν τ τ-neutrino A. Geiser, Was bedeutet Masse? 3 τtau
4 Fermion Mass from Higgs field? very brilliant scientist (fermion) works with speed of light! -> massless room = vacuum people = Higgs vacuum expectation value A. Geiser, Was bedeutet Masse? 4
5 Fermion Mass from Higgs field? scientist becomes famous! enters room with people A. Geiser, Was bedeutet Masse? 5
6 Fermion Mass from Higgs field? people cluster around him hamper his movement/working speed -> he becomes massive! A. Geiser, Was bedeutet Masse? 6
7 Quantum Numbers and Mass 1948: discovery of muon same quantum numbers as electron, except mass I.I. Rabi (Nobel 1944) Who ordered THAT? (Nobel 1988) muon decay: µ - -> ν µ e - ν e conservation of electric charge Leon M. Melvin Jack Ledermann Schwartz Steinberger lepton number: ν = ν (1955) muon number : ν µ = ν e (1962) There is a distinct neutrino for each charged lepton A. Geiser, Was bedeutet Masse? 7
8 Mass vs. structure of the proton E ~ MeV resolve whole proton static quark model, valence quarks (m ~ 350 MeV) Jerome I. Friedmann Henry W. Kendall (Nobel 1990) Richard E. Taylor E ~ m p ~ 1 GeV resolve valence quarks and their motion E >> 1 GeV resolve quark and gluon sea A. Geiser, Was bedeutet Masse? 8
9 Inside the proton Low Q 2 (large λ) Medium Q 2 (medium λ) Heisenberg s UP allows gluons, and qq pairs to be produced for a very short time. Large Q 2 (short λ) At higher and higher resolutions, the quarks emit gluons, which also emit gluons, which emit quarks, which. At highest Q 2, λ ~ 1/Q ~ m A. Geiser, Was bedeutet Masse? 9
10 The Forces in Nature at ~ 1 GeV A. Geiser, Was bedeutet Masse? 10
11 Screening of Electric Charge and Mass electric charge polarises vacuum -> virtual electron positron pairs virtual pairs partially screen electron charge and mass (Nobel 1965) effective charge/force/mass decreases at large distances/low energy (screening) increases at small distance/large energy Sin-Itoro Julian Richard P A. Geiser, Was bedeutet Masse? 11 Tomonaga Schwinger Feynman
12 Anti-Screening of Coulour Charge/Mass! quark-antiquark pairs -> screening gluons carry colour -> gg pairs -> anti-screening! confinement asymptotic freedom 1/r 2 ~E 2, A. Geiser, Was bedeutet Masse? 12
13 The power of symmetries: Parity Will physical processes look the same when viewed through a mirror? In everyday day life: violation of parity symmetry is common natural : our heart is on the left spontaneous : cars drive on the right (on the continent) What about basic interactions? Eugene Wigner (Nobel 1963) Electromagnetic and strong interactions conserve parity! A. Geiser, Was bedeutet Masse? 13
14 The power of symmetries: Parity Lee & Yang 1956: weak interactions violate Parity experimentally verified by Wu et al. 1957: Chen Ning Yang spin consequence: neutrinos are always lefthanded! (antineutrinos righthanded) A. Geiser, Was bedeutet Masse? 14 (Nobel 1957) Tsung -Dao Lee Chieng Shiung Wu
15 How much do Neutrinos weigh? Standard Model has m ν = 0 -> evidence for m ν = 0 + parity violation forces nothing? or almost nothing? A. Geiser, Was bedeutet Masse? 15
16 Neutrinos in Cosmology artist s view of the Big Bang ~400 ν s / cm 3! dark matter?? A. Geiser, Was bedeutet Masse? 16
17 Why do we need colliders? early discoveries in cosmic rays, but need controlled conditions Mont Blanc m = E c 2 need high energy to discover new heavy particles colliders = microscopes LEP/LHC A. Geiser, Was bedeutet Masse? 17 CERN
18 Weak Interactions The Theory of GLASHOW, SALAM and WEINBERG ~ (Nobel 1979) Theory of the unified weak and electromagnetic interaction, transmitted by exchange of intermediate vector bosons A. Geiser, Was bedeutet Masse? 18
19 Discovery of the W and Z (1983) To produce the heavy W and Z bosons (m ~ GeV) need high energy collider! : conversion of SPS proton accelerator at CERN into proton-antiproton collider challenge: make antiproton beam! success! -> first W and Z produced 1982/83 (Nobel 1984) Z 0 -> e + e - UA1 Carlo Rubbia Simon van der Meer A. Geiser, Was bedeutet Masse? 19
20 The Quest for the Higgs at LHC Higgs production: LEP Higgs decay: depending on mass, Higgs might be found within first year of LHC physics operation! A. Geiser, Was bedeutet Masse? 20
21 The Quest for Unification of Forces Electroweak Unification Grand Unified Theories? Maxwell s equations Superstring Theories? electric magnetic strong Big Bang weak gravity A. Geiser, Was bedeutet Masse? 21
22 Cosmology increasing energy -> going further backwards in time in the universe -> getting closer to the Big Bang What do we know about the Mass of the Universe? A. Geiser, Was bedeutet Masse? 22
Weak Interactions. The Theory of GLASHOW, SALAM and WEINBERG
Weak Interactions The Theory of GLASHOW, SALAM and WEINBERG ~ 1959-1968 (Nobel 1979) Theory of the unified weak and electromagnetic interaction, transmitted by exchange of intermediate vector bosons mass
String Theory in the LHC Era
String Theory in the LHC Era J Marsano (marsano@uchicago.edu) 1 String Theory in the LHC Era 1. Electromagnetism and Special Relativity 2. The Quantum World 3. Why do we need the Higgs? 4. The Standard
Overview. The quest of Particle Physics research is to understand the fundamental particles of nature and their interactions.
Overview The quest of Particle Physics research is to understand the fundamental particles of nature and their interactions. Our understanding is about to take a giant leap.. the Large Hadron Collider
A first trip to the world of particle physics
A first trip to the world of particle physics Itinerary Massimo Passera Padova - 13/03/2013 1 Massimo Passera Padova - 13/03/2013 2 The 4 fundamental interactions! Electromagnetic! Weak! Strong! Gravitational
Fundamental Particles and Forces
Fundamental Particles and Forces A Look at the Standard Model and Interesting Theories André Gras PHYS 3305 SMU 1 Overview Introduction to Fundamental Particles and Forces Brief History of Discovery The
Particle Physics. Tommy Ohlsson. Theoretical Particle Physics, Department of Physics, KTH Royal Institute of Technology, Stockholm, Sweden
Particle Physics Tommy Ohlsson Theoretical Particle Physics, Department of Physics, KTH Royal Institute of Technology, Stockholm, Sweden International Baccalaureate T. Ohlsson (KTH) Particle Physics 1/
Most of Modern Physics today is concerned with the extremes of matter:
Most of Modern Physics today is concerned with the extremes of matter: Very low temperatures, very large numbers of particles, complex systems Æ Condensed Matter Physics Very high temperatures, very large
Most of Modern Physics today is concerned with the extremes of matter:
Most of Modern Physics today is concerned with the extremes of matter: Very low temperatures, very large numbers of particles, complex systems Æ Condensed Matter Physics Very high temperatures, very large
1. What does this poster contain?
This poster presents the elementary constituents of matter (the particles) and their interactions, the latter having other particles as intermediaries. These elementary particles are point-like and have
Chapter 32 Lecture Notes
Chapter 32 Lecture Notes Physics 2424 - Strauss Formulas: mc 2 hc/2πd 1. INTRODUCTION What are the most fundamental particles and what are the most fundamental forces that make up the universe? For a brick
Introduction. Read: Ch 1 of M&S
Introduction What questions does this field address? Want to know the basic law of nature. Can we unify all the forces with one equation or one theory? Read: Ch 1 of M&S K.K. Gan L1: Introduction 1 Particle
Discovery of the W and Z 0 Bosons
Discovery of the W and Z 0 Bosons Status of the Standard Model ~1980 Planning the Search for W ± and Z 0 SppS, UA1 and UA2 The analyses and the observed events First measurements of W ± and Z 0 masses
I. Antoniadis CERN. IAS CERN Novice Workshop, NTU, 7 Feb 2014
I. Antoniadis CERN IAS CERN Novice Workshop, NTU, 7 Feb 2014 1 2 3 the Large Hadron Collider (LHC) Largest scientific instrument ever built, 27km of circumference >10 000 people involved in its design
The God particle at last? Astronomy Ireland, Oct 8 th, 2012
The God particle at last? Astronomy Ireland, Oct 8 th, 2012 Cormac O Raifeartaigh Waterford Institute of Technology CERN July 4 th 2012 (ATLAS and CMS ) A new particle of mass 125 GeV I The Higgs boson
The God particle at last? Science Week, Nov 15 th, 2012
The God particle at last? Science Week, Nov 15 th, 2012 Cormac O Raifeartaigh Waterford Institute of Technology CERN July 4 th 2012 (ATLAS and CMS ) A new particle of mass 125 GeV Why is the Higgs particle
Lecture 03. The Standard Model of Particle Physics. Part II The Higgs Boson Properties of the SM
Lecture 03 The Standard Model of Particle Physics Part II The Higgs Boson Properties of the SM The Standard Model So far we talked about all the particles except the Higgs If we know what the particles
An Introduction to Particle Physics
An Introduction to Particle Physics The Universe started with a Big Bang The Universe started with a Big Bang What is our Universe made of? Particle physics aims to understand Elementary (fundamental)
Particle Physics A short History
Introduction to Experimental Particle Physics Heavily indebted to 1. Steve Lloyd Queen Mary s College, London 2004 2. Robert S. Orr University of Toronto 2007 3. Z. Vilakazi University of Cape Town -2006
Nuclear and Particle Physics 3: Particle Physics. Lecture 1: Introduction to Particle Physics February 5th 2007
Nuclear and Particle Physics 3: Particle Physics Lecture 1: Introduction to Particle Physics February 5th 2007 Particle Physics (PP) a.k.a. High-Energy Physics (HEP) 1 Dr Victoria Martin JCMB room 4405
Lecture 11. Weak interactions
Lecture 11 Weak interactions 1962-66: Formula/on of a Unified Electroweak Theory (Glashow, Salam, Weinberg) 4 intermediate spin 1 interaction carriers ( bosons ): the photon (γ) responsible for all electromagnetic
Weak interactions and vector bosons
Weak interactions and vector bosons What do we know now about weak interactions? Theory of weak interactions Fermi's theory of weak interactions V-A theory Current - current theory, current algebra W and
PH5211: High Energy Physics. Prafulla Kumar Behera Room: HSB-304B
PH5211: High Energy Physics Prafulla Kumar Behera E-mail:behera@iitm.ac.in Room: HSB-304B Information Class timing: Wed. 11am, Thur. 9am, Fri. 8am The course will be graded as follows: 1 st quiz (20 marks)
Elementary Particle Physics Glossary. Course organiser: Dr Marcella Bona February 9, 2016
Elementary Particle Physics Glossary Course organiser: Dr Marcella Bona February 9, 2016 1 Contents 1 Terms A-C 5 1.1 Accelerator.............................. 5 1.2 Annihilation..............................
An Introduction to Modern Particle Physics
An Introduction to Modern Particle Physics Mark Thomson University of Cambridge Y Z X Science Summer School: 30 th July - 1 st August 2007 1 Course Synopsis Introduction : Particles and Forces - what are
Quantum Numbers. Elementary Particles Properties. F. Di Lodovico c 1 EPP, SPA6306. Queen Mary University of London. Quantum Numbers. F.
Elementary Properties 1 1 School of Physics and Astrophysics Queen Mary University of London EPP, SPA6306 Outline Most stable sub-atomic particles are the proton, neutron (nucleons) and electron. Study
Option 212: UNIT 2 Elementary Particles
Department of Physics and Astronomy Option 212: UNIT 2 Elementary Particles SCHEDULE 26-Jan-15 13.pm LRB Intro lecture 28-Jan-15 12.pm LRB Problem solving (2-Feb-15 1.am E Problem Workshop) 4-Feb-15 12.pm
Option 212: UNIT 2 Elementary Particles
Department of Physics and Astronomy Option 212: UNIT 2 Elementary Particles SCHEDULE 26-Jan-15 13.00pm LRB Intro lecture 28-Jan-15 12.00pm LRB Problem solving (2-Feb-15 10.00am E Problem Workshop) 4-Feb-15
A Brief History of Particle Physics
A Brief History of Particle Physics 1930s The known 'Elementary Particles' were : electron proton neutron (inside the nucleus) 'neutrino' (now anti-neutrino) in beta decay photon the quantum of the electromagnetic
Lecture 10: Weak Interaction. 1
Lecture 10: Weak Interaction http://faculty.physics.tamu.edu/kamon/teaching/phys627/ 1 Standard Model Lagrangian http://pdg.lbl.gov/2017/reviews/rpp2017-rev-standard-model.pdf Standard Model Lagrangian
FACULTY OF SCIENCE. High Energy Physics. WINTHROP PROFESSOR IAN MCARTHUR and ADJUNCT/PROFESSOR JACKIE DAVIDSON
FACULTY OF SCIENCE High Energy Physics WINTHROP PROFESSOR IAN MCARTHUR and ADJUNCT/PROFESSOR JACKIE DAVIDSON AIM: To explore nature on the smallest length scales we can achieve Current status (10-20 m)
Some fundamental questions
Some fundamental questions What is the standard model of elementary particles and their interactions? What is the origin of mass and electroweak symmetry breaking? What is the role of anti-matter in Nature?
Beyond the standard model? From last time. What does the SM say? Grand Unified Theories. Unifications: now and the future
From last time Quantum field theory is a relativistic quantum theory of fields and interactions. Fermions make up matter, and bosons mediate the forces by particle exchange. Lots of particles, lots of
Physics Beyond the Standard Model. Marina Cobal Fisica Sperimentale Nucleare e Sub-Nucleare
Physics Beyond the Standard Model Marina Cobal Fisica Sperimentale Nucleare e Sub-Nucleare Increasingly General Theories Grand Unified Theories of electroweak and strong interactions Supersymmetry
Le Modèle Standard et ses extensions
Particules Élémentaires, Gravitation et Cosmologie Année 2007-08 08 Le Modèle Standard et ses extensions Cours III: 15 février f 2008 Weak Interactions: from Fermi s s model to a gauge theory 15 fevrier
The Discovery of the Higgs Boson: one step closer to understanding the beginning of the Universe
The Discovery of the Higgs Boson: one step closer to understanding the beginning of the Universe Anna Goussiou Department of Physics, UW & ATLAS Collaboration, CERN Kane Hall, University of Washington
Experimental Tests of the Standard Model. Precision Tests of the Standard Model
Experimental Tests of the Standard Model Precision Tests of the Standard Model - History of EW theory - Discovery of the Z and W Boson by the UA1/UA2 experiments (1983) - Precision tests of the Z sector
Electron-positron pairs can be produced from a photon of energy > twice the rest energy of the electron.
Particle Physics Positron - discovered in 1932, same mass as electron, same charge but opposite sign, same spin but magnetic moment is parallel to angular momentum. Electron-positron pairs can be produced
The Scale-Symmetric Theory as the Origin of the Standard Model
Copyright 2017 by Sylwester Kornowski All rights reserved The Scale-Symmetric Theory as the Origin of the Standard Model Sylwester Kornowski Abstract: Here we showed that the Scale-Symmetric Theory (SST)
The discovery of W ± and Z 0 vector-bosons
The discovery of W ± and Z 0 vector-bosons Giulia De Zordo April 15, 2014 Abstract This article is about the discovery of the W ± and Z 0 vector-bosons, the carriers of weak interaction. The discovery
Particle Physics. All science is either physics or stamp collecting and this from a 1908 Nobel laureate in Chemistry
Particle Physics JJ Thompson discovered electrons in 1897 Rutherford discovered the atomic nucleus in 1911 and the proton in 1919 (idea of gold foil expt) All science is either physics or stamp collecting
Particle Physics. Dr Victoria Martin, Spring Semester 2012 Lecture 1: The Mysteries of Particle Physics, or Why should I take this course?
Particle Physics Dr Victoria Martin, Spring Semester 2012 Lecture 1: The Mysteries of Particle Physics, or Why should I take this course? Contents: Review of the Standard Model! What we know! What we don
Experimental verification of the Salaam-Weinberg model. Pásztor Attila, Eötvös University Experimental Particle Physics Student Seminar
Experimental verification of the Salaam-Weinberg model Pásztor Attila, Eötvös University Experimental Particle Physics Student Seminar Contents Theoretical considerations Discovery of W and Z bosons (and
Matter: it s what you have learned that makes up the world Protons, Neutrons and Electrons
Name The Standard Model of Particle Physics Matter: it s what you have learned that makes up the world Protons, Neutrons and Electrons Just like there is good and evil, matter must have something like
The mass of the Higgs boson
The mass of the Higgs boson LHC : Higgs particle observation CMS 2011/12 ATLAS 2011/12 a prediction Higgs boson found standard model Higgs boson T.Plehn, M.Rauch Spontaneous symmetry breaking confirmed
IX. Electroweak unification
IX. Electroweak unification The problem of divergence A theory of weak interactions only by means of W ± bosons leads to infinities e + e - γ W - W + e + W + ν e ν µ e - W - µ + µ Divergent integrals Figure
Particle physics today. Giulia Zanderighi (CERN & University of Oxford)
Particle physics today Giulia Zanderighi (CERN & University of Oxford) Particle Physics Particle Physics is fundamental research, as opposed to many applied sciences (medicine, biology, chemistry, nano-science,
Leptons and Weak interactions
PHY771, 8/28/2014 Tomasz Skwarnicki 1 Historical introduction to Elementary Particles: Leptons and Weak interactions Tomasz Skwarnicki Syracuse University Griffiths, 2 nd ed., 1.3-1.5,1.10 PHY771, 8/28/2014
Intro to Particle Physics and The Standard Model. Robert Clare UCR
Intro to Particle Physics and The Standard Model Robert Clare UCR Timeline of particle physics Ancient Greeks Rutherford 1911 Rutherford Chadwick Heisenberg 1930 s Hofstader Gell-Mann Ne eman 1960 s Timeline
Weak interactions, parity, helicity
Lecture 10 Weak interactions, parity, helicity SS2011: Introduction to Nuclear and Particle Physics, Part 2 2 1 Weak decay of particles The weak interaction is also responsible for the β + -decay of atomic
Particles, Energy, and Our Mysterious Universe
Particles, Energy, and Our Mysterious Universe 1 The End of Physics "The more important fundamental laws and facts of physical science have all been discovered, and these are now so firmly established
Confronting Theory with Experiment at the LHC
Confronting Theory with Experiment at the LHC Mojtaba Mohammadi Najafabadi School of Particles and Accelerators 21 st IPM Physics Spring Conference May 21-22, 2014 1 Standard Model: a theory of interactions
The achievements of the CERN proton antiproton collider
The achievements of the CERN proton antiproton collider Luigi DiLella Scuola Normale Superiore, Pisa, Italy Motivation of the project The proton antiproton collider UA1 and UA2 detectors Discovery of the
1 Introduction. 1.1 The Standard Model of particle physics The fundamental particles
1 Introduction The purpose of this chapter is to provide a brief introduction to the Standard Model of particle physics. In particular, it gives an overview of the fundamental particles and the relationship
The Uncertainty Principle and the Quarks
The Uncertainty Principle and the Quarks Andrei Gritsan Johns Hopkins University August, 2007 JHU Quarknet Meeting Outline The Uncertainty Principle quantum mechanics with elementary particles The Quarks
Chapter 46. Particle Physics and Cosmology
Chapter 46 Particle Physics and Cosmology Atoms as Elementary Particles Atoms From the Greek for indivisible Were once thought to be the elementary particles Atom constituents Proton, neutron, and electron
Particle + Physics at ATLAS and the Large Hadron Coillder
Particle + Physics at ATLAS and the Large Hadron Coillder Discovering the elementary particles of the Universe Kate Shaw The International Centre for Theoretical Physics + Overview Introduction to Particle
The first one second of the early universe and physics beyond the Standard Model
The first one second of the early universe and physics beyond the Standard Model Koichi Hamaguchi (University of Tokyo) @ Colloquium at Yonsei University, November 9th, 2016. Credit: X-ray: NASA/CXC/CfA/M.Markevitch
Introduction to Elementary Particle Physics. Note 01 Page 1 of 8. Natural Units
Introduction to Elementary Particle Physics. Note 01 Page 1 of 8 Natural Units There are 4 primary SI units: three kinematical (meter, second, kilogram) and one electrical (Ampere 1 ) It is common in the
Phys 102 Lecture 28 Life, the universe, and everything
Phys 102 Lecture 28 Life, the universe, and everything 1 Today we will... Learn about the building blocks of matter & fundamental forces Quarks and leptons Exchange particle ( gauge bosons ) Learn about
The Higgs Boson. Triumph of the Standard Model. Jesse Thaler
The Higgs Boson Triumph of the Standard Model Jesse Thaler Higgs-like Celebration Oct 11, 2012 Culminating a century of particle physics! Defining next 25 years of fundamental physics! Higgs-like Discovery
Elementarteilchenphysik. Weak interaction
Elementarteilchenphysik Antonio Ereditato LHEP University of Bern Weak interaction 1 Weak Interaction Weak interaction is the only interaction that does not produce fermion bound states: weakness and short
Electroweak Theory: The Experimental Evidence and Precision Tests PPP-II Lecture 8 (FS 2012)
1 Electroweak Theory: The Experimental Evidence and Precision Tests PPP-II Lecture 8 (FS 2012) Michael Dittmar (ETH-Zürich/CMS) 17.4.2012 1950ies From the messy world of hadrons to weak decays and neutrinos.
Frontier Science: The mystery of Antimatter
Frontier Science: The mystery of Antimatter Cristina Lazzeroni Professor in Particle Physics STFC Public Engagement Fellow ASE Frontier Science Lecture University of Birmingham Poynting Physics S02 7th
Fundamental Particles
Fundamental Particles Standard Model of Particle Physics There are three different kinds of particles. Leptons - there are charged leptons (e -, μ -, τ - ) and uncharged leptons (νe, νμ, ντ) and their
Chapter 29 Lecture. Particle Physics. Prepared by Dedra Demaree, Georgetown University Pearson Education, Inc.
Chapter 29 Lecture Particle Physics Prepared by Dedra Demaree, Georgetown University Particle Physics What is antimatter? What are the fundamental particles and interactions in nature? What was the Big
Particle Physics Outline the concepts of particle production and annihilation and apply the conservation laws to these processes.
Particle Physics 12.3.1 Outline the concept of antiparticles and give examples 12.3.2 Outline the concepts of particle production and annihilation and apply the conservation laws to these processes. Every
Hc 5: Outline. Book by Tipler, chapter 12.2
Hc 5: Outline Introduc:on Produc:on and iden:fica:on of par:cles Basic concepts: par:cle- an:par:cle, leptons and hadrons Fundamental interac:ons and force carriers Conserva:on laws and symmetries The
Introduction to the Standard Model
Introduction to the Standard Model Bill Murray, RAL, Quarks and leptons Bosons and forces The Higgs March 2002 1 Outline: An introduction to particle physics What is the Higgs Boson? Some unanswered questions
Mysteries of the Standard Model
Mysteries of the Standard Model Methods of exploring the nature of the Electroweak force at the Compact Muon Solenoid [CMS] experiment. Final REU presentation given by Kellen McGee in partial fulfillment
FYS3510 Subatomic Physics. Exam 2016
FYS3510 Subatomic Physics VS 2015 Farid Ould-Saada Exam 2016 In addition to the items marked in blue, don t forget all examples and related material given in the slides, including the ones presented during
Lecture 18 - Beyond the Standard Model
Lecture 18 - Beyond the Standard Model Why is the Standard Model incomplete? Grand Unification Baryon and Lepton Number Violation More Higgs Bosons? Supersymmetry (SUSY) Experimental signatures for SUSY
Wesley Smith, U. Wisconsin, January 21, Physics 301: Introduction - 1
Wesley Smith, U. Wisconsin, January 21, 2014 Physics 301: Introduction - 1 Physics 301: Physics Today Prof. Wesley Smith, wsmith@hep.wisc.edu Undergraduate Physics Colloquium! Discussions of current research
Lecture PowerPoint. Chapter 32 Physics: Principles with Applications, 6 th edition Giancoli
Lecture PowerPoint Chapter 32 Physics: Principles with Applications, 6 th edition Giancoli 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the
Outline. Charged Leptonic Weak Interaction. Charged Weak Interactions of Quarks. Neutral Weak Interaction. Electroweak Unification
Weak Interactions Outline Charged Leptonic Weak Interaction Decay of the Muon Decay of the Neutron Decay of the Pion Charged Weak Interactions of Quarks Cabibbo-GIM Mechanism Cabibbo-Kobayashi-Maskawa
Electroweak Symmetry Breaking
Electroweak Symmetry Breaking An enduring mystery of the standard model of particle physics and how we hope to solve it David Schaich Department of Physics and Center for Computational Science Boston University
Chapter 1. Introduction
Chapter 1 Introduction 1.1 Fundamental Forces Particle physics is concerned with the fundamental constituents of matter and the fundamental forces through which the fundamental constituents interact among
Bosons in the Zoo of Elementary Particles
Bosons in the Zoo of Elementary Particles Daniele Sasso * Abstract In this paper we want to raise the question concerning the physical identity of bosons and the function that they perform in the Non-Standard
Introduction to Particle Physics and the Standard Model. Robert Clare UCR
Introduction to Particle Physics and the Standard Model Robert Clare UCR Timeline of particle physics Ancient Greeks Rutherford 1911 Rutherford Chadwick Heisenberg 1930 s Hofstader Gell-Mann Ne eman 1960
Saturday Morning Physics -- Texas A&M University. What is Matter and what holds it together? Dr. Rainer J. Fries. January 27, 2007
Saturday Morning Physics -- Texas A&M University Particles and Forces What is Matter and what holds it together? Dr. Rainer J. Fries January 27, 2007 Zooming in on the World around us Particles and Forces
Saturday Morning Physics -- Texas A&M University Dr. Rainer J. Fries
Saturday Morning Physics -- Texas A&M University Particles and Forces What is Matter and what holds it together? Dr. Rainer J. Fries January 27, 2007 Zooming in on the World around us Particles and Forces
Physics 662. Particle Physics Phenomenology. February 21, Physics 662, lecture 13 1
Physics 662 Particle Physics Phenomenology February 21, 2002 Physics 662, lecture 13 1 Physics Beyond the Standard Model Supersymmetry Grand Unified Theories: the SU(5) GUT Unification energy and weak
Cosmology and particle physics
Cosmology and particle physics Lecture notes Timm Wrase Lecture 5 The thermal universe - part I In the last lecture we have shown that our very early universe was in a very hot and dense state. During
High Energy Physics. Lecture 9. Deep Inelastic Scattering Scaling Violation. HEP Lecture 9 1
High Energy Physics Lecture 9 Deep Inelastic Scattering Scaling Violation HEP Lecture 9 1 Deep Inelastic Scattering: The reaction equation of DIS is written e+ p e+ X where X is a system of outgoing hadrons
Understanding the balance of matter and antimatter in the Universe
Understanding the balance of matter and antimatter in the Universe Physicists in the College of Arts and Sciences have made important discoveries regarding Bs meson particles -- something that may explain
Introduction to the Standard Model of elementary particle physics
Introduction to the Standard Model of elementary particle physics Anders Ryd (Anders.Ryd@cornell.edu) May 31, 2011 Abstract This short compendium will try to explain our current understanding of the microscopic
SFB 676 selected theory issues (with a broad brush)
SFB 676 selected theory issues (with a broad brush) Leszek Motyka Hamburg University, Hamburg & Jagellonian University, Krakow Physics of HERA and goals of the Large Hadron Collider The Higgs boson Supersymmetry
Essentials of Particle Physics
Essentials of Particle Physics Kajari Mazumdar Department of High Energy Physics Tata Institute of Fundamental Research Mumbai http://www.tifr.res.in/~mazumdar Kajari.Mazumdar@gmail.com KSTA Lecture Series
Lecture 23. November 16, Developing the SM s electroweak theory. Fermion mass generation using a Higgs weak doublet
Lecture 23 November 16, 2017 Developing the SM s electroweak theory Research News: Higgs boson properties and use as a dark matter probe Fermion mass generation using a Higgs weak doublet Summary of the
The Particle World. This talk: What is our Universe made of? Where does it come from? Why does it behave the way it does?
The Particle World What is our Universe made of? Where does it come from? Why does it behave the way it does? Particle physics tries to answer these questions. This talk: particles as we understand them
Astronomy 182: Origin and Evolution of the Universe
Astronomy 182: Origin and Evolution of the Universe Prof. Josh Frieman Lecture 12 Nov. 18, 2015 Today Big Bang Nucleosynthesis and Neutrinos Particle Physics & the Early Universe Standard Model of Particle
REALIZING EINSTEIN S DREAM. Exploring Our Mysterious Universe
REALIZING EINSTEIN S DREAM Exploring Our Mysterious Universe Mysteries of the Universe Quarks Leptons Higgs Bosons Supersymmetric Particles SuperString Theory Dark Matter Dark Energy and the cosmological
4. The Standard Model
4. The Standard Model Particle and Nuclear Physics Dr. Tina Potter Dr. Tina Potter 4. The Standard Model 1 In this section... Standard Model particle content Klein-Gordon equation Antimatter Interaction
INTRODUCTION TO THE STANDARD MODEL OF PARTICLE PHYSICS
INTRODUCTION TO THE STANDARD MODEL OF PARTICLE PHYSICS Class Mechanics My office (for now): Dantziger B Room 121 My Phone: x85200 Office hours: Call ahead, or better yet, email... Even better than office
FUNDAMENTAL PARTICLES CLASSIFICATION! BOSONS! QUARKS! FERMIONS! Gauge Bosons! Fermions! Strange and Charm! Top and Bottom! Up and Down!
FUNDAMENTAL PARTICLES CLASSIFICATION! BOSONS! --Bosons are generally associated with radiation and are sometimes! characterized as force carrier particles.! Quarks! Fermions! Leptons! (protons, neutrons)!
High Energy Physics. QuarkNet summer workshop June 24-28, 2013
High Energy Physics QuarkNet summer workshop June 24-28, 2013 1 The Birth of Particle Physics In 1896, Thompson showed that electrons were particles, not a fluid. In 1905, Einstein argued that photons
3 Dimensional String Theory
3 Dimensional String Theory New ideas for interactions and particles Abstract...1 Asymmetry in the interference occurrences of oscillators...1 Spontaneously broken symmetry in the Planck distribution law...3
Lecture 2: The First Second origin of neutrons and protons
Lecture 2: The First Second origin of neutrons and protons Hot Big Bang Expanding and cooling Soup of free particles + anti-particles Symmetry breaking Soup of free quarks Quarks confined into neutrons
DESY, 12. September Precision Electroweak Measurements. Stefan Roth RWTH Aachen
DESY, 12. September 2006 Precision Electroweak Measurements Stefan Roth RWTH Aachen Outline 1. Theory of electroweak interaction 2. Precision measurements of electroweak processes 3. Global electroweak
The W boson weighs in
Particle physicists caught their first glimpse of the boson in January 1983. Now they have measured its mass so precisely that the Standard Model is under threat The boson weighs in THEY look like s, they
Discovery of the Higgs Boson
Discovery of the Higgs Boson Seminar: Key Experiments in Particle Physics Martin Vogrin Munich, 22. July 2016 Outline Theoretical part Experiments Results Open problems Motivation The SM is really two