quantum+particles AS

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Created by
Alaina Davies

Cards (37)

  • Types of particles
    • Hadrons
    • Leptons
  • Leptons
    Fundamental particles, examples are electron, positron, neutrinos
  • Hadrons
    Can be split into baryons and mesons
  • Baryons
    • Made of quarks
  • Mesons
    • Made of a quark and an antiquark
  • Quarks are fundamental particles as far as we know
  • Baryons have three quarks, mesons have two quarks (a quark and an antiquark)
  • Quarks are held together by the strong nuclear force
  • Examples of baryons and mesons
    • Neutron
    • Proton
    • Pion
  • Baryon number
    Conserved quantity for baryons
  • Lepton number
    Conserved quantity for leptons
  • Four fundamental forces
    • Electromagnetic (gauge boson: virtual photon)
    • Strong nuclear (gauge boson: gluon)
    • Weak (gauge bosons: W+, W-)
    • Gravity (hypothetical gauge boson: graviton)
  • Strong nuclear force

    • Keeps nucleus together by overcoming electrostatic repulsion of protons
    • Has a short range of attraction, around 3-4 fm
  • Mass-energy equivalence
    E = mc^2
  • Annihilation
    Particle and antiparticle collide and are destroyed, energy converted to photons
  • Pair production
    Photon with sufficient energy turns into a particle-antiparticle pair
  • Types of ionizing radiation
    • Alpha
    • Beta
    • Gamma
  • Alpha radiation

    • Highly ionizing, weakly penetrating, stopped by paper or few cm of air
  • Beta radiation
    • Medium ionizing and penetrating, stopped by few mm of aluminium
  • Gamma radiation
    • Weakly ionizing, highly penetrating, reduced by concrete
  • Alpha decay

    Nucleus emits alpha particle (helium nucleus)
  • Beta decay

    Neutron converts to proton, emitting electron and antineutrino
  • Feynman diagram shows beta minus decay: neutron -> proton + W- -> proton + electron + antineutrino
  • Conservation rules: charge, lepton number, baryon number conserved, strangeness conserved in strong interactions
  • Muon
    Heavy electron
  • Isotopes
    Same element, different number of neutrons
  • Specific charge
    Charge to mass ratio
  • Electron volt (eV)

    Energy gained by electron accelerated through 1 volt
  • Photoelectric effect
    Photons of sufficient energy liberate electrons from metal surface
  • Photoelectric effect

    Proved light has particle nature, not just wave nature
  • Measuring photoelectron kinetic energy

    Use stopping potential to counteract electron kinetic energy
  • De Broglie wavelength

    Wavelength associated with a particle, given by h/p
  • Electron diffraction
    Electrons diffract around atoms, producing interference pattern
  • Fluorescent tube
    Electrons emitted by cathode, excite mercury gas atoms, which emit UV photons that then excite phosphor coating to emit visible light
  • Electron energy levels
    Electrons can be excited to higher levels by absorbing photons or collisions
  • Ionization level

    Energy level where electron can escape atom/molecule completely
  • Absorption and emission spectra

    Absorption spectrum shows what wavelengths are absorbed, emission spectrum shows what wavelengths are emitted