1. Nuclear Energy Nuclear Fission - the splitting of two atoms
Nuclear fusion – the combining of 2 atoms
Both processes release energy

2. Atomic structure
Atoms are composed of protons , neutrons and electrons – discovered in the 1930’s
Protons – positively charged
q= ×10−19 C
m= × kg
Neutrons – no charge
m= x kg
Electron –negative charge
q =− ×10−19 C
m= ×10-31 kg

3. Atomic structure Protons and neutrons make up the nucleus
Electrons orbit the nucleus at specific distances known as energy levels
Atomic number = number of protons=Z
Atomic mass number = A = Z+ N, where N is the number of neutrons
Atomic mass = total mass of the electrons, protons and neutrons
Atomic weight = the ratio of the average mass of an atom to 1/12 of the mass of an atom of carbon-12.
Ion –if an atom loses or gains an electron and has a net charge
Isotope-atom has the same number of protons but different number of neutrons

4. Atomic Structure Atoms are held together by forces
There are four forces in nature
Gravity -force between masses
Electrostatic forces-like charges repel, unlike charges attract
Strong nuclear force - causes an attraction between protons and neutrons
Weak nuclear force – causes protons to transform into neutrons and neutrons in to protons

5. Atomic Structure
In atoms, the electrostatic force is holding the electrons to the nucleus, since the electrons are negatively charged and the protons are positively charged.
The protons in the nucleus are being pushed apart by the electrostatic force since they have the same charge, but the strong nuclear force overcomes this repulsion on the atomic size scales and holds the protons together.

6. Fission
In the late 1930s, it was discovered that if a uranium nucleus was bombarded by neutrons, it absorbed the neutron and became an unstable isotope of uranium, which then spilt into 2 separate atoms (Krypton and Barium) and emitted more neutrons and gamma rays

7. Is mass conserved?
Now the mass of the fission products plus the excess neutron should equal the mass of the initial incident neutron and the uranium. But it doesn’t.
Where did the mass go?
Well, remember E = mc2 - mass cannot be created or destroyed, only converted to and from energy, so the missing mass must be converted into energy.

8. How much energy 200 MeV is released per fission event
The fission of 1 g of uranium or plutonium per day liberates about 1 MW.
This is the energy equivalent of 3 tons of coal or about 600 gallons of fuel oil per day
No CO2 emissions!
Vastly superior in terms of energy per amount of fuel

9. Self sustaining or chain reaction
The fission reaction itself releases neutrons, these can be used to fission additional nuclei, so the elements are there for a sustained or chain reaction.
Tremendous power capability made this an ideal weapon.

10. Fission Bombs
Created in response to a fear that Nazi Germany would develop one first, which would tip the balance of power and possibly the outcome of WWII in their favor.
Manhattan Project – Secret US project to develop a nuclear weapon
Developed 3 nuclear devices, one with 235U and two with 239PU.
One was tested in New Mexico in 1945, the other two were dropped on Hiroshima and Nagasaki Japan in August 1945, ending WWII in the Pacific.

11. Critical Mass
In order to sustain a chain reaction, one needs a specific amount of fissionable material, called the critical mass
Critical mass is the smallest amount of fissile material needed for a sustained nuclear chain reaction.
Creating the critical mass was one of the challenges that faced the Manhattan project

12. The devices Fat Man and Little Boy
Little Boy – device dropped on Hiroshima
Gun-type device
One mass of U-235, the "bullet," is fired down a gun barrel into another mass of U-235, rapidly creating the critical mass of U-235, resulting in an explosion.

13. The devices Fat Man Tested in New Mexico and dropped on Nagasaki
Used Plutonium rather than Uranium
Implosion style device
The required implosion was achieved
by using shaped charges with
many explosive lenses to produce
the perfectly spherical explosive
wave which compressed the
plutonium sphere.

14. Effects of a Fission explosion
Blast Damage
Thermal radiation
Electromagnetic Pulse
Ionizing radiation
earthquake

15. Blast Damage 40-50% of the total energy released is in the blast.
Most of the destruction due to blast effects
Blast wind may exceed 1000 km/h.

16. Thermal Radiation
35-45% of the energy released is in thermal radiation
Burns occur
Eye injures
Flash Blindness-caused by the initial bright flash, can last up to 40 minutes
Retinal burns – scarring due to the direct concentration of explosions thermal energy on the eye-rare the fireball needs to be in the direct line of sight
Firestorms-gale force winds that blow in from all sides towards the center of a fire

17. Electromagnetic pulse
The nuclear explosion produced high energy electromagnetic radiation-Gamma rays.
The Gamma rays interact with (scatter) electrons and produce higher energy electrons.
Long metal objects (cables, etc) act as antenna and generate high voltages and currents, which can damage or destroy electrical equipment.
No known biological effects, though useful against Sentinels (The Matrix).

18. Ionizing radiation About 5% of the energy
In the form of neutrons, gamma rays, alpha particles and electrons, moving at nearly the speed of light
Neutrons transmutate (change the atomic structure of) the surrounding matter, often making it radioactive. This adds to the radioactive fallout

19. What does this have to do with Nuclear Energy
It sets the historical context and shows the power released
To point out that this is NOT what will happen if there is an accident in a nuclear power facility-they do not “blow up” like explosive devices. More on that later

20. Nuclear reactor
In a nuclear power plant, the energy to heat the water to create steam to drive the turbine is provided by the fission of uranium, rather than the burning of coal.
Fuel is 3% 235U and 97% 238U. 235U is an isotope of 238U. The chain reaction will only occur in the 235U, but naturally occurring uranium has both present in it.
The neutrons coming from a fission reaction have an energy of 2Mev. They are too energetic to sustain a nuclear reaction in 235U.
Need to slow them down to energies on the order of 10-2 so they can sustain fission in the 235U

21. Slowing the neutrons down
A moderator is used to slow down the neutrons and cause them to lose energy
The moderator could be water or graphite
The lower energy neutrons are called thermal neutrons
Some of the neutrons will be absorbed by 235U instead of causing a fission reaction or by 238U and resulting in the emission of a gamma ray in both cases.
Absorption of a neutron by 238U can result in the creation of 239Pu which is also fissionable

22. Creating Plutonium So: 238U captures a neutron creating 239U
239U undergoes a beta decay in with a half life of 24 minutes and becomes 239Np (Neptunium)
239Np then beta decays with a half life of 2.3 days into 239Pu.
239Pu has a half life of 24,000 years
239Pu can also undergo fission by the slow neutrons in the core, with an even higher probability
So as it builds up in the core, is contributes to the fission reaction

23. Breeder reactor
A reactor designed to produce more fuel (usually 239Pu ) than it consumes.
239Pu does not occur naturally, and it is more fissile than 235U.
Leads to the possibility of reactors that can create their own fuel, and only need limited mounts of naturally occurring uranium to operate.
Also leads to the danger of countries creating additional nuclear fuels for weapons development
Caution-reactor must be designed to produce weapons grade plutonium, jut because someone has a nuclear reactor does not mean they create weapons grade plutonium

24. Reactor design PWR – pressurized water reactor
Core – where the action is. Fuel assembly is kept in here (fuel is usually in the form of fuel rods)
Fuel rods are surrounded by the water which acts as the moderator. This water is kept under high pressure so it never boils-it heats a seconds water source which turns into steam
Control rods are slid in and out from the top to control the fission rate-in an emergency they can be dropped completely into the reactor core, quenching the fission
Once the steam is generated, this works just like a fossil fuel power plant
Can run without refueling for up to 15 years if the initial fuel is highly enriched
Used in submarines and commercial power systems

25. Reactor design BWR –Boiling water reactor
Core – where the action is. Fuel assembly is kept in here (fuel is usually in the form of fuel rods)
Fuel rods are surrounded by the water which acts as the moderator and the source of steam
Control rods are slid in and out from the bottom to control the fission rate-in an emergency they can be dropped completely into the reactor core, quenching the fission. Also, boron can be added to the water which also efficiently absorbs neutron
Once the steam is generated, this works just like a fossil fuel power plant

26. Fuel Cycle Fuel rods typically stay in a reactor about 3 years
When they are removed, they are thermally and radioactively hot
To thermally cool them they are put in a cooling pond.
Initial idea was that they would stay in the cooling pond for 150 days, then be transferred to a facility which would reprocess the uranium an plutonium for future use.

27. Nuclear waste disposal
This idea ran into problems.
Fear that the plutonium would be easily available for weapons use halted reprocessing efforts in 1977
Note that it is very difficult to extract weapons grade plutonium from spent fuel rods
Plan is now to bury the waste deep underground, in a place called Yucca Mountain, Nevada

28. Nuclear waste The spent fuel rods are radioactive
Radioactivity is measured in curies
A curie is 3.7x1010 decays per second
A 1000 MW reactor would have 70 megacuries of radioactive waste once it was shut down
After 10 years, this has decayed to 14 MCi
After 100 years, it is 1.4MCi
After 100,000 years it is 2000 Ci