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Nuclear Physics

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Nuclear Physics UConn Mentor Connection Mariel Tader The Standard Model Describes three of the four fundamental forces Electromagnetism, weak and strong ... – PowerPoint PPT presentation

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Title: Nuclear Physics


1
Nuclear Physics
  • UConn Mentor Connection
  • Mariel Tader

2
The Standard Model
  • Describes three of the four fundamental forces
  • Electromagnetism, weak and strong interactions
  • There are 12 different kinds of elementary
    particles

3
The Forces
  • Electromagnetism why opposites attract
  • Biology/ Chemistry
  • Strong Force holds quarks together
  • Weak Force mediates fundamental particle decay
  • (Gravity) not included in Standard Model

4
Electroweak Theory
  • Electromagnetism and weak force are two different
    aspects of the same force electroweak
  • The two merge into the same force at high
    energies and close distance

5
The particles
  • 6 Quarks make up protons, neutrons, etc.
  • 6 Leptons electrons,
  • neutrinos, etc.
  • Force carriers
  • gluons for strong
  • force, etc.
  • Weak forces range
  • The three generations

6
Antimatter
  • Each type of particle has a comparable
    anti-particle
  • The same properties, except charge
  • The mystery why so much more matter?
  • Annihilation matter and antimatter collide a
    Z boson/gluon/photon form decay into new
  • matter/ antimatter pair

7
The Nucleus
  • Quarks come in threes (protons/ neutrons/ etc.)
    or twos (mesons)
  • Gluons hold quarks together, force carrier
    particle for strong force

8
Quantum Numbers
  • Electric Charge all particles except quarks have
    integer charge, quark charges add to whole
    numbers
  • Flavor different kinds of quarks/ leptons
  • Spin goes by 1/2s, particles/ nuclei
  • Lepton/baryon numbers, etc.
  • Color Charge gets its own slide
  • Angular momentum/ momentum location
  • Weak Charge strength of weak force

9
Color Charge
  • Why quarks come in threes or twos neutral charge
  • Why quarks stay together color force field
  • Quark 1 of 3 colors
  • Anti-quark 1 of 3 anti-colors
  • Gluon color charges 1 color and 1 anti-color
    combination

10
Bosons and Fermions
  • Pauli Exclusion Principle
  • two particles cant have identical sets of
    quantum numbers
  • Fermions obey Pauli
  • Bosons violate Pauli

11
Radiation
  • Unstable nuclei decay
  • Alpha release of 2 protons/2 neutrons (helium
    nucleus)
  • Beta release of an electron
  • Gamma release of photons (as gamma rays)
  • Neutron radiation like it sounds

12
Fundamental Particle Decay
  • Unlike atoms, fundamentals can not break into
    constituents
  • To become a less massive particle
  • Emit a force carrier (W boson) virtual
  • W boson immediately decays into lighter particles

13
Virtual Particles
  • Can not be detected directly
  • Can break conservation of energy for a very
    short time

You can not see virtual particles, but you can
see the before and after
14
The Project
  • Thomas Jefferson National Accelerator
  • The collaboration
  • Will be the first to observe and study exotic
    mesons
  • Will begin 2014

15
gluex
  • GlueX hopes to learn about quarks, gluons, and
    confinement by creating exotic mesons
  • How we see the gluons
  • Polarized beam liquid hydrogen target
    exotic mesons final particles and radiation
    data deciphered


16
Bremsstrahlung
  • German for braking radiation
  • A radiation particle interacts with atoms and
    creates more radiation, while
  • losing the
  • corresponding
  • energy

Atom
17
Coherent Bremsstrahlung
  • Must be in a crystal
  • Particle/crystal must be in correct
    alignment
  • A few specific wavelengths are prevalent,
    peaks

18
Reciprocal Lattice Vectors
  • Bravais Lattice repeating crystalline
    arrangements of points
  • Reciprocal Lattice
  • made from the vectors
  • perpendicular to three
  • of the vectors of the original
  • Used as a simple geometric model that can
    interpret diffraction in crystals

19
Framing the Crystal
  • A frame would produce too much unwanted bremms.
  • diamond is mounted
  • on tiny carbon fibers
  • The resonant frequency of
  • the fibers should be known,
  • to minimize rotation

20
Vibration
  • Interference two or more superimposed waves
    create a new wave pattern need coherent bremss.
  • Resonant frequency An objects natural frequency
    of vibration
  • Gluonic flux tube vibration is like a string

21
The Carbon Wire
  • The theoretical model vs. the experimental data
  • How we modeled it
  • The glue ball equation
  • How we measured it
  • Uncertainty bars

22
Polarization
  • The orientation of the waves electric/ magnetic
    fields
  • Transverse wave polarization is perpendicular to
    waves direction
  • Linear Polarization
  • the electric or magnetic
  • field is oriented in
  • one direction, i.e. no
  • rotation (chirality)

23
Putting it all together
  • The process Electron beam diamond wafer
    polarized photons hit mesons detectors
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