First some Introductory Stuff => On The Web.

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Transcription:

First some Introductory Stuff => On The Web http://hep.physics.utoronto.ca/~orr/wwwroot/phy357/phy357s.htm

PHY357 = What is the Universe Made Of?

Is the Universe Made of These? Proton = (u u d) held together by gluons Neutron = (u d d)

Quantum Forces In Quantum Field Theory, particles interact via: Exchange of virtual particles Electrons interact by exchanging: Virtual Photons - EM Force Quarks interact by exchanging: Virtual Gluons Color Force

Higgs Boson Electromagnetism on its own can be made to give finite results for all calculations. Unified Electroweak theory gives infinite results for process like: Become finite if include new particle Higgs boson ± 0 Spontaneous Symmetry Breaking Renormalizable Gauge Theory Higgs makes W Z massive, and actually generates masses of fundamental particles. It is a quantum field permeating the universe.

How Does Higgs Generate Mass? In vacuum, a photon: has velocity c and has zero mass In glass, a photon: has velocity < c, same as an effective mass Refractive Index This is due to photon interacting with electromagnetic field in condensed matter By analogy can understand masses of particles generated by Higgs Field in vacuum

Grand Unification. At a high enough energy electromagnetism weak force strong (colour) force become aspects of Grand Unified Force

Understand History of Universe? What we think (thought?) visible matter is made of.

Measuring Ω = ρ ρ 0 0 C Amazingly enough can measure Total matter/energy density in universe Seems equal to critical density for flat space/time Measure temperature fluctuations in remnant of fireball from Big Bang. Ω 0 = 1.003 ± 0.013 Map of sky temp ~ 3 Kelvin

Density of Standard Model Matter Referred to as Baryonic Matter Density is Ω B If Universe is made of quarks & leptons Ω B = Ω 0 = 1 Ω B measured from abundance of elements produced in nucleosynthesis of Big Bang. Deuterium, Helium, Lithium Ω B = Ω 0.044 Ω B 0 Most of Universe is not Standard Model matter. Some kind of Dark Matter

Density of All Matter Ω M Can measure density of all matter, whatever its nature,,by looking at gravitational motion Ω M rotation curves of galaxies motion of galactic clusters Fit to global parameters of Universe Ω = 0.26 ± 0.012 There is indeed Dark Matter M Ω 0 = 1 So even with this Dark Matter, cannot account for Universe must be 75% Something Else

Dark Energy Ω Λ If the expansion of the Universe is being slowed down by gravitational attraction; expect that in remote past galaxies were moving apart more rapidly than now. Observations of distant supernovae show that in the past galaxies were moving apart more slowly Expansion is accelerating Ω Λ = 085. ± 02. ( 0.4 ± 01. ) + ( 085. ± 02. ) = 125. ± 022. Ω M + Ω Λ = 1 Driven by some quantum field permeating the Universe.

Need for Supersymmetry In Grand Unified Theories cannot Unify forces, unless postulate unseen form of matter Higgs mass runs away to Plank Scale Three forces never have same strength Unless all particles have supersymmetric sparticle partners (of higher mass) + Sleptons Bosinos Squarks Spin 1 Spin1/2

SUSY + Dark Matter Supersymmetric Particles are unstable Susy Normal + Susy Eventually decay chain ends in Normal matter + lightest SUSY particle Lightest SUSY particle cannot interact with normal matter Lightest SUSY particle good candidate for Dark Matter Hope to produce (SUSY - antisusy ) pairs and Higgs at Large Hadron Collider

How to Make Matter / AntiMatter? Colliding high energy beams Energy of beams transformed into mass of new particles p p LHC will be proton - proton collider For SUSY observation must contain ALL visible energy, in order to infer invisible SUSY

CERN Seen from the Air Tunnels of CERN accelerator complex superimposed on a map of Geneva. Accelerator is 50 m underground 25 km in circumference

Superconducting Magnet 8 Tesla In order to accelerate protons to high energy, must bend them in circular accelerator 7 TeVmomentum needs intense magnetic field

Underground

ATLAS Cavern February 2003

ATLAS Cavern November 2004

LAr and Tile Calorimeters Tile barrel Tile extended barrel LAr hadronic end-cap (HEC) LAr EM end-cap (EMEC) LAr EM barrel LAr forward calorimeter (FCAL)

HEC 2 A-wheel on the insertion stand, Aug. 2004

LAr Forward Calorimeters FCAL C assembly into tube Fall 2003

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