Particle physics

Created by

Lucy

Cards (84)

Proton
Charge: +1.6x10^-19
Mass: 1.67x10^-27
Specific charge: 9.58x10^7
Neutron
Charge: 0 Mass: 1.67x10^-27
Specific charge: 0
Electron
Charge: -1.6x10^-19
Mass: 9.11x10^-31
Specific charge: 1.76x10^11
Specific charge
charge / mass
Isotopes
atoms with the same number of protons but different number of neutrons
Strong nuclear force
keeps nuclei stable by counteracting the electrostatic force of repulsion between protons in the nucleus.
only acts of nucleons
short range (attractive up to separations of 3fm but repulsive below separators of 0.5fm)
Shape of graph for SNF
shape:
Unstable nuclei
have too many protons or neutrons or both.
in this case, the SNF is able to keep them stable
Decay
the type of decay will depend on the amount of protons and neutrons there are
when does alpha decay occur?
When there are too many of both protons and neutrons
alpha decay
Proton number decreases by 2
Nucleon number decreases by 4
alpha decay equation
.
beta minus decay occurs when...
occurs when nuclei are neutron rich
beta minus decay
proton number increases by 1
nucleon number stays the same
beta minus decay equation
.
anitparticles
For every particle there is an anitparticle which has the same rest energy and mass but all other properties are opposite
antiparticle pairs
electron and positron
electron neutrino and electron antineutrino
Electromagnetic radiation
travels in packets called photons
These transfer energy and have no mass
Photons
energy of photons is directly proportional to the frequency of electromagnetic radiation.
Equation: E = hf = hc/wavelength
h
is Planck's constant = 6.63 x 10^-34
Annihilation
occurs when a particle and it's corresponding antiparticle collide and as a result their masses are converted into energy.
what happens to photons in annihilation?
the energy released from annihilation is released in the form of 2 photons moving (because they have kinetic energy) in the opposite directions (in order to conserve momentum)
example of application of annihilation
PET scanner which allows 3D images of inside the body to be taken making medical diagnoses easier.
done by introducing a positron-emitting radioisotope into the patient, and when positrons are released, they annihilate with electrons in the patient's system which will emit gamma photons which are easily detected
Pair production
a photon converted into an equal amount of matter and antimatter
when can pair production occur?
When the photon has energy greater than the total rest mass of both particles
What happens to excess energy in pair production?
Converted into kinetic energy
What are the 4 fundamental forces?
Gravity
Electromagnetic
Weak nuclear
Strong nuclear
Forces between particles are caused by exchange particles
Exchange particles
Carry energy and momentum between the particles experiencing the force.
Strong interaction
exchange particles: Gluon
range /m: 3x10^-15
acts on: Hadrons
Weak interaction
exchange particles: W boson (+ and -) range /m: 10^-18 acts on: All particles
electromagnetic interaction

exchange particles: virtual photon
range /m: infinite
acts on: charged particles
gravity
exchange particles: Graviton
range /m: infinite
acts on: particles with mass
Weak nuclear force
responsible for beta decay, electron capture and electron-proton collisions
electron capture
p + e- --> n + electron neutrino using W+ boson
electron-proton collision
p + e- --> n + electron neutrino using W- boson
Classification of particles
All particles are either hadrons or leptons
Leptons
Leptons are fundamental particles meaning they can not be broken down any further. They do not experience the strong nuclear force.
Hadrons
hadrons are formed from quarks and they do experience the strong force
quarks
are fundamental particles