particle and quantum physics

Created by

will reid

Cards (86)

Atom 
Formed of 3 constituents: protons, neutrons and electrons
Nucleus 
Formed of protons and neutrons, also known as nucleons
Electrons 
Orbit the nucleus in shells
Particle properties 
Charge (C)
Relative Charge
Mass (kg)
Relative Mass
Specific Charge (C/kg)
Proton 
Charge: +1.6 x 10^-19 C, Relative Charge: +1, Mass: 1.67 x 10^-27 kg, Relative Mass: 1, Specific Charge: 9.58 x 10^7 C/kg
Neutron 
Charge: 0, Relative Charge: 0, Mass: 1.67 x 10^-27 kg, Relative Mass: 1, Specific Charge: 0 C/kg
Electron 
Charge: -1.6 x 10^-19 C, Relative Charge: -1, Mass: 9.11 x 10^-31 kg, Relative Mass: 0.0005, Specific Charge: 1.76 x 10^11 C/kg
Specific charge 
Charge-mass ratio of a particle
Proton number (Z) 
Number of protons in an atom
Nucleon number (A) 
Number of protons and neutrons in an atom
Isotopes 
Atoms with the same number of protons but different numbers of neutrons
Carbon-14 
Radioactive isotope of carbon used in carbon dating
Carbon dating 
Calculating the approximate age of an object containing organic material by measuring the percentage of carbon-14 remaining
Strong nuclear force (SNF) 
Keeps nuclei stable by counteracting the electrostatic force of repulsion between protons
The SNF is attractive up to separations of 3 fm, but repulsive below separations of 0.5 fm
Unstable nuclei 
Have too many of either protons, neutrons or both, causing the SNF to not be enough to keep them stable
Alpha decay 
1. Proton number decreases by 2
2. Nucleon number decreases by 4
Beta-minus decay 
1. Proton number increases by 1
2. Nucleon number stays the same
Energy was not conserved in beta-minus decay, leading to the discovery of neutrinos
Antiparticle 
Has the same rest energy and mass but all other properties are opposite the particle
Particle properties 
Mass (kg)
Rest energy (MeV)
Charge (C)
Electron neutrino 
Mass: 0 kg, Rest energy: 0 MeV, Charge: 0 C
Electron antineutrino 
Mass: 0 kg, Rest energy: 0 MeV, Charge: 0 C
Photon 
Electromagnetic radiation that travels in packets and transfers energy, has no mass
Energy of photons 
Directly proportional to the frequency of electromagnetic radiation, E = hf
Annihilation 
A particle and its corresponding antiparticle collide, their masses are converted into energy released as 2 photons
PET scanner 
Uses annihilation of positrons and electrons to produce 3D images of the inside of the body
Pair production 
A photon is converted into an equal amount of matter and antimatter
Fundamental forces 
Gravity
Electromagnetic
Weak nuclear
Strong nuclear
Exchange particles 
Carry energy and momentum between particles experiencing a force
Exchange particles for each force 
Gravity: Graviton (not on specification)
Electromagnetic: Virtual photon (γ)
Weak: W boson (W+ or W-)
Strong: Gluon
Electron capture 
p + e- → n + νe
Electron-proton collision 
p + e- → n + νe
Beta-plus decay 
p → n + e+ + νe
Beta-minus decay 
n → p + e- + νe
Hadrons 
Particles formed of quarks that experience the strong nuclear force
Leptons 
Fundamental particles that do not experience the strong nuclear force
Types of hadrons 
Baryons (formed of 3 quarks)
Antibaryons (formed of 3 antiquarks)
Mesons (formed of a quark and antiquark)
Baryon number 
Shows whether a particle is a baryon (1), antibaryon (-1), or not a baryon (0)
Baryon number is always conserved in particle interactions