Post on 26-Dec-2015
Nuclear Physics
Physics 12
Protons, Neutrons and Electrons
The atom is composed of three subatomic particles:
ParticleCharge(in C)
SymbolMass
(in kg)
Electron -1.602x10-19 e- 9.109 56x10-31
Proton 1.602x10-19 p+ 1.672 614x10-27
Neutron 0 n0 1.674 920x10-27
Atomic Nucleus Atom described
using: X – atomic symbol A – atomic mass
number (nucleon number)
Z – atomic number Number of protons
and electrons = Z Number of
neutrons = A - Z
AZX
Strong Nuclear Force
The electrostatic forces inside a nucleus would rip it apart if there was not another force
By the end of the 1930’s physicists had determined that nucleons attract each other
This is the strongest force in the known universe
Stability and the Nucleus Although the Strong Nuclear Force is
strong enough to hold a small nucleus together, as the size of the nucleus becomes larger, the electrostatic forces begin to become more important
As a result, if we consider various nuclei based on their Atomic Number and Neutron Number we get the following result:
Stability and the NucleusEach black dot represents a stable nucleus, with the number of neutrons shown on the vertical axis and the number of protons on the horizontal axis
Nuclides and Isotopes
Nuclides are different combinations of nucleons
Isotopes occur when an element (specific Atomic Number) has different numbers of neutrons (different Atomic Mass Numbers)
For example, there are three common isotopes of hydrogen:
Nuclides and Isotopes
Nuclear Binding Energy
It takes 13.6 eV to separate an electron from a hydrogen atom
However, it takes more than 20 MeV to separate a neutron from a helium-4 atom
The energy to separate all the nucleons in a nucleus is called the binding energy
Larger nuclei are held together a little less tightly than those in the
middle of the Periodic Table
Mass Defect If you were able to apply the 20 MeV required to
separate a neutron from helium-4, what would happen to it?
This is dealt with using Einstein’s Special Theory of Relativity and the fact that mass and energy are equivalent E = mc2
The mass of helium-4 (2p, 2n) is smaller than that of helium-3 (2p, 1n) and a neutron
The energy that was added to remove the neutron was converted into mass
The difference between the mass of a nuclide and the sum of the masses of its constituents is called mass defect
Atomic Mass Unit (u) When dealing with nucleons, it is often
more useful to deal with mass in unified atomic mass units (u) instead of kilograms
ParticleMass
(in kg)Mass(in u)
Electron 9.109 56x10-31 0.000 549
Proton 1.672 614x10-27 1.007 276
Neutron 1.674 920x10-27 1.008 665
Binding Energy Example
Determine the binding energy in electron volts and joules for an iron-56 nucleus given that the nuclear mass is 55.9206u
55.9206
56
26
30
nucleusm u
A
Z
N A Z
N
Binding Energy Example
Determine the binding energy in electron volts and joules for an iron-56 nucleus given that the nuclear mass is 55.9206u
26(1.007276 ) 30(1.008665 )
56.449126
56.449126 55.9206
0.5285
total p n
total
total
m Zm Nm
m u u
m u
m u u
m u
Binding Energy Example
We would expect the binding energy per nucleon to be about 8MeV:
2
8 2
11
11
19
8
0.5285 (3.00 x 10 / )
7.888 10
7.888 10
1.602 10 /
4.924 10
E mc
E u m s
E x J
x JE
x J eV
E x eV
864.924 10
8.79 1056
x eVx eV
Radioactive Isotopes
In discussing the nucleus, we looked at a plot of stable nuclei
It is also possible to have a nucleus that is not stable (meaning that it will fall apart)
An unstable nucleus will decay following a few very specific processes
We call this decay radioactivity and classify it into one of three types
Radioactive Isotopes
Alpha Decay An alpha particle (α) is a helium nucleus
(two protons and two neutrons) A nucleus that emits an alpha particle will
lose the two protons and two neutrons Large nuclei will emit alpha particles They do not penetrate matter well and a
sheet of paper or 5cm of air will stop most They can free electrons from atoms,
meaning they are a form of ionizing radiation
Alpha Decay
Beta Decay When a nucleus emits a beta particle
(β), it appears to lose an electron or positron from within the nucleus
There are two types of beta decay (β- and β+)
Beta particles can penetrate matter to a greater extent than alpha particles; they can penetrate about 0.1mm of lead or 10m of air
They are also a form of ionizing radiation but less damaging than alpha particles
Beta Decay (β-) In this type of beta decay, a neutron
becomes a proton and a β- particle (high energy electron) is emitted
In addition an antineutrino ( ) is emitted (antimatter) along with the beta minus particle
The nucleus’s atomic number increases by one while the atomic mass number remains the same
Beta Decay (β-)
Beta Decay (β+) In this type of beta decay, a proton
becomes a neutron and a β+particle (high energy positron or antielectron) is emitted
In addition a neutrino ( ) is emitted along with the beta plus particle
The nucleus’s atomic number decreases by one while the atomic mass number remains the same
Beta Decay (β+)
Gamma Decay (γ) When a nucleus goes through alpha or
beta decay, the daughter nucleus is often left in an excited state
In order to reduce the energy of the nucleus, it will go through gamma decay (high energy photon) to return to the ground state
Gamma radiation can pass through 10cm of lead or 2km of air
It is the most damaging of all due to the energy of the gamma particle
Gamma Decay
Decay Series
When a large nucleus decays by alpha and beta radiation, the daughter nucleus will be more stable than the original nucleus
However, the daughter nucleus may still be unstable and will itself go through alpha or beta radiation
This leads to a decay series
Rate of Radioactive Decay It is impossible to predict when a specific
nucleus will decay You can describe the probability of decay The concept of half life is used with
radioactive decay: the time required for half of the sample to decay
Using the half life equation, it is possible to determine how much of a sample would remain after a given period of time
Half Life
N sample remaining N0 original sample Δt elapsed time T half life
0
1
2
tT
N N
Half Life