Quarks, Leptons, Bosons, the LHC and all that. Tony Liss OLLI Lecture September 23, 2008.

Slides:

Advertisements

Similar presentations

Bruce Kennedy, RAL PPD Particle Physics 2 Bruce Kennedy RAL PPD.

Advertisements

Going Smaller than Atoms AQA Syllabus A A Level Physics – Module 2 © T Harrison. The National School.

"Now I am become Death, the destroyer of worlds." Robert Oppenheimer after the first test of the atomic bomb.

Higgs Boson, Dark Matter and Black Holes: Revolutionizing the Laws of the Universe with the LHC Ashutosh Kotwal Duke University.

ATLAS Experiment at CERN. Why Build ATLAS? Before the LHC there was LEP (large electron positron collider) the experiments at LEP had observed the W and.

Bruce Kennedy, RAL PPD Particle Physics 2 Bruce Kennedy RAL PPD.

Tony Liss Saturday Physics for Everyone November 9, 2013 (With debts to Chris Quigg, Leonard Susskind, Hitoshi Murayama)

AAAS 2001 San Francisco1 Supersymmetry The Coming Revolutions in Particle Physics Hitoshi Murayama (UC Berkeley)

1 The Future of Particle Physics Steve King, University of Southampton, Masterclass, 24th March, 2009.

Discovering the Unknown at the CERN Large Hadron Collider (LHC) Amy Gladwin University of Arizona.

Laura Gilbert How We Study Particles. The basics of particle physics! Matter is all made up of particles… Fundamental particle: LEPTON Fundamental particles:

January 2011 David Toback, Texas A&M University Texas Junior Science and Humanities Symposium 1 David Toback Texas A&M University Texas Junior Science.

Smashing the Standard Model: Physics at the CERN LHC

1 The Large Hadron Collider and Beyond Steve King, University of Southampton, Masterclass, 24th March, 2010.

March 2011 David Toback, Texas A&M University Davidson Scholars 1 David Toback Texas A&M University Davidson Scholars March 2011 The Big Bang, Dark Matter.

DISCOVERING THE QUANTUM UNIVERSE Jonathan Feng University of California, Irvine Physical Sciences Breakfast Lecture Series Beckman Center of the National.

Modern Physics LECTURE II.

J. Nielsen1 The ATLAS experiment at the Large Hadron Collider Jason Nielsen UC Santa Cruz VERTEX 2004 July 28, 2010.

8/5/2002Ulrich Heintz - Quarknet Particle Physics what do we know? Ulrich Heintz Boston University.

Particle Physics From Strings To Stars. Introduction  What is Particle Physics?  Large Hadron Collider (LHC)  Current Experiments – ALICE – ATLAS –

October 2011 David Toback, Texas A&M University Research Topics Seminar 1 David Toback Texas A&M University Research Topics Seminar September 2012 Cosmology.

LHC’s Second Run Hyunseok Lee 1. 2 ■ Discovery of the Higgs particle.

A superconducting proton collider Kevin Stenson University of Colorado – Boulder July 31, 2008.

January 2009 David Toback, Saturday Morning Physics 1 Prof. David Toback Texas A&M University January 2014 Dark Matter and the Big Bang Theory.

CERN, 21 February 2001 Egil Lillestøl, CERN & Univ. of Bergen Recorded at

Particle Physics at the Energy Frontier Tevatron → LHC & The Very Early Universe Tony LissAir Force Institute of TechnologyApril 10, 2008.

1 Back to class 10/22/04 Ian Shipsey Quarks and the Cosmos Ian Shipsey(*) (*) one of 15 astrophysicists & particle physicists at Purdue University A lecture.

ROY, D. (2011). Why Large Hadron Collider?. Pramana: Journal Of Physics, 76(5), doi: /s

Particle Physics J4 Leptons and the standard model.

The Higgs Boson: without the maths and jargon David Hall Graduate Seminar Series St Catherine’s College MCR 11 th May 2011.

My Chapter 30 Lecture.

Joseph Haley Joseph Haley Overview Review of the Standard Model and the Higgs boson Creating Higgs bosons The discovery of a “Higgs-like” particle.

The Dark Side of the Universe What is dark matter? Who cares?

Nicolo Cartiglia -INFN Torino1 Very difficult questions about elementary particle physics Friendly chat at Lucia’s school.

Point 1 activities and perspectives Marzio Nessi ATLAS plenary 2 nd October 2004 Large Hadron Collider (LHC)

School of Arts & Sciences Dean’s Coffee Presentation SUNY Institute of Technology, February 4, 2005 High Energy Physics: An Overview of Objectives, Challenges.

The Large Hadron Collider is the world's largest and highest-energy particle accelerator.

Atomic theory explains what the world is and how it’s held together. The Atom.

Particle Physics Quiz EPPOG Hands on Particle Physics Masterclasses 2011.

Recreating the Big Bang with the World’s Largest Machine Prof Peter Watkins Head of Particle Physics Group The University of Birmingham Admissions Talk.

Particles and Strings Nick Evans “The search for a fundamental theory of the building blocks of nature and their interactions” University of Southampton.

What is the Higgs??? Prof Nick Evans University of Southampton.

A singularity formed by a previous collapsed Universe? Multiple Universes? We just don’t know… YET What Caused It?

ATLAS experiment at the CERN Large Hadron Collider Peter Watkins, Head of Particle Physics Group, University of Birmingham, UK

GRIDFest, CERN, October 3, New Physics at the Large Hadron Collider Jos Engelen CERN a brief introduction.

Alpha S. A measure of the strongest fundamental force of nature- The Strong Force.

SubAtomic Physics & Astrophysics Intimate Connexion between Very Large and Very Small.

Re-creating the Big Bang Experiments at the Large Hadron Collider Dr Cormac O’ Raifeartaigh (WIT) Albert Einstein Ernest Walton.

Modern Physics. Reinventing Gravity  Einstein’s Theory of Special Relativity  Theorizes the space time fabric.  Describes why matter interacts.  The.

Introduction to CERN Activities

The Higgs Boson Observation (probably) Not just another fundamental particle… July 27, 2012Purdue QuarkNet Summer Workshop1 Matthew Jones Purdue University.

CERN, 8 February, 2001 Egil Lillestøl, CERN & Univ. of Bergen Lectures recorded at :

Searching for New Matter with the D0 Experiment Todd Adams Department of Physics Florida State University September 19, 2004.

Compelling Scientific Questions The International Linear Collider will answer key questions about matter, energy, space and time We now sample some of.

Energy-Mass Equivalence

What about the Higgs Boson? What precisely is the Higgs? We describe dynamics of a system via a Lagrangian – One can completely replicate all of Newtonian.

1 Particle Physics, The Mysteries of the Universe, and The LHC Nhan Tran Johns Hopkins University.

1 The Standard Model of Particle Physics Owen Long U. C. Riverside March 1, 2014.

Particle Detectors January 18, 2011 Kevin Stenson.

1 LHCb CMS ALICE ATLAS The ATLAS experiment at the LHC 27 km.

Phy107 Fall From Last Time… Particles are quanta of a quantum field –Often called excitations of the associated field –Particles can appear and.

LHC LARGE HADRON COLLIDER World’s largest and highest-energy particle accelerator. Built by the European Organization for Nuclear Research(CERN). To study.

NS1300 – Emergence of Modern Science The Particle Zoo.

Standard Model of Particle Physics

The Standard Model of Particle Physics

Cosmology and Particle Physics in a Single Experiment

Elementary particles Spring 2005, Physics /24/2018 Lecture XXV.

Particle Physics what do we know?

The Mysteries of Particle Physics and how we are trying to solve them

The World’s Largest Experiment

Presentation transcript:

Quarks, Leptons, Bosons, the LHC and all that. Tony Liss OLLI Lecture September 23, 2008

Some HE Physicist Principles We are reductionists (and proud of it!) –Our worldview is that there are a small number of fundamental constituents, interacting via a small number of forces, that make up the Universe as we know it. –This picture has worked extremely well for about 2000 years. –The modern version has been untangled using particle beams of ever increasing energy.

???? The Standard Model The matter around us is made up of “quarks” and “leptons” And held together by four forces, each with a force carrier: A proton is made of u u d Add an electron to make a hydrogen atom Electromagnetic Strong Weak Gravity

The Standard Model The matter around us is made up of “quarks” and “leptons” particleadventure.org The marriage of quantum mechanics and special relativity required that antiparticles exist. Helium Atom

Why High Energy? From quantum theory we know ~ 1/p Wavelength is inversely proportional to momentum If you want to see small things you need short wavelengths (that’s why electron microscopes were invented) and short wavelengths means high momentum (and energy). From relativity we know E=Mc 2 If you want to create a heavy particle (large M) you need a lot of energy.

Unification of the Forces Electric Magnetic Weak Strong Electromagnetic Electroweak “Low Energy” “High Energy” “Very (very)High Energy” Theory works up to ~here That’s the region we want to probe with the LHC. Part way to Einstein’s dream! Higgs Bosons born here?

CERN- LHC

Fermilab Protons & anti- protons collide at 2 TeV (2 x electron volts) The worlds highest energy particle accelerator!!

Fermilab Makes Top Quarks The heaviest known elementary particle. Discovered in 1994! Why is it so heavy?? We don’t know

The Large Hadron Collider The world’s largest, highest energy, accelerator 300 feet underground outside of Geneva, Switzerland. The LHC collides intense beams of protons 40 million times per second at “14 TeV” 2.7mi

France Switzerland GrapesCows

Inside the Tunnel

ATLAS Detector at CERN

ATLAS is VERY BIG

ATLAS

Who Is ATLAS? ATLAS is one of four large experiments at LHC –The ATLAS collaboration consists of ~2500 physicists including ~700 graduate students from 169 different institutions in 37 different countries ATLAS is a United Nations of particle physics.

ATLAS, The Movie

Some of What LHC Can Study Higgs Boson –Understanding M Supersymmetry –Dark Matter? Extra Dimensions –Quantum Gravity/String Theory Dark Energy –We don’t even know how to look for this Heavy gauge bosons –New forces? Precision top quark studies –New physics? Diboson production –From the Higgs? Quark and lepton substructure –Are fundamental particles fundamental? etc.

Let’s Pick Two Higgs Boson Supersymmetry

What is “The Higgs”? Named after Peter Higgs It “gives mass” to the fundamental particles (if, in fact, it exists) Without the Higgs (or something) the theory requires that all these fundamental particles have M=0. But we know that’s not the case.

F=Ma The idea is that the Higgs field exists throughout all space. As particles try to move through this field they interact with it and are “slowed down”. Heavier particles are those that interact more strongly M=F/a In quantum mechanics there is a particle associated with a field (quantum of the field). The photon is the quantum of the electromagnetic field. The Higgs boson is the quantum of the Higgs Field.

Finding the Higgs The Higgs “couples to mass” –It decays to the heaviest particles available Easy, but rare Hard, but copious

This is a simulation of the production and decay of a Higgs to two Z bosons. The Z bosons themselves decay, one to a pair of electrons and the other to a pair of muons. e+e-e+e- +-+-

Supersymmetry (SUSY) Every quark, lepton and force carrier has a SUSY partner (sparticles). –Sparticles would be made copiously in the early (HOT) universe. –They all decay away quickly, except for the lightest one (neutralino), which has nowhere to go. Make SUSY particles at an accelerator:

SUSY & Unified Forces Why is this an attractive idea? SUSY helps with unifying the forces. SUSY is a necessary ingredient of quantum gravity theories. We know that the universe is filled with dark matter. –Dark matter is not made of quarks and leptons – the Standard Model has no dark matter candidates. –Dark matter interacts very weakly with normal matter (or else we would have found it already). –The lightest SUSY particle is a perfect candidate. Einstein’s dream of a “Unified Field Theory”, now needs SUSY: Energy Strength of force No SUSY Energy Strength of force SUSY EM weak strong

Dark Matter

Dark Matter’s Everywhere Speed of stuff out here Doesn’t match luminous matter in here! In Galaxies Motion of a galaxy out here Doesn’t agree with luminous matter in here The “Hydra” Galactic Cluster And clusters of galaxies

Physics 211 Momentum is “conserved” –Before the protons collide they have equal and opposite momentum: The total momentum is zero. –Therefore: The total momentum of all the stuff created in the collision must also be zero.

A Simulated SUSY Event Missing momentum carried away by invisible particle

About Those Black Holes… Creating microscopic black holes at the LHC would be –A MAJOR BREAKTHROUGH IN SCIENCE! –INCREDIBLY EXCITING –NOBEL PRIZE STUFF –NOT AT ALL DANGEROUS –REALLY

About Black Holes The microscopic black holes that might be created at LHC are so small they evaporate instantly according to Steven Hawking. –But what if Hawking’s wrong? Cosmic rays reach much higher energies than the LHC and have been having collisions for billions of years – any black holes created have not done much damage.

About Black Holes Black holes don’t suck everything in. –Only stuff inside the Schwarzschild radius. –If the sun suddenly became a black hole, the Earth’s orbit would not change (but we’d get very cold). The Schwarzschild radius of the sun is 3 kilometers. –The Schwarzschild radius of a 1 TeV black hole is about m – that’s about 1/1000 th of the size of a proton. There’s nothing around such a black hole for it to suck in!

Final Words After 25 years of planning and 15 years of design and construction, the LHC is finally about to turn on. This is the chance of a lifetime. Our understanding of the way the Universe works is about to be revolutionized. –We just don’t know exactly how…