Splitting The Atom
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Transcript of Splitting The Atom
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Splitting The Atom
Nuclear Fission
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Fission
• Large mass nuclei split into two or more smaller mass nuclei– Preferably mass numbers closer to 56
• Neutrons also emitted
• Fission can occur when – unstable large mass atom captures a neutron– can happen spontaneously
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Fission is Exothermic
• Masses resulting nuclei < original mass~0.1% less
• “Missing mass” converted into energy E = mc2
• Large quantities of energy are released because the products are higher up the Binding Energy Curve
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The Fission Process
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Energy Released By A Fission
• U + n --> fission + 2 or 3 n + 200 MeV1MeV (million electron volts) = 1.609 x 10-13 j
• This corresponds to 3.2 x 10-11 j
• Production of one molecule of CO2 in fossil fuel combustion only generates 4 ev or 6.5 x 10-19 j of energy
• This is 50,000,000 times more energy
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Fissile Nuclei
• Not all nuclei are capable of absorbing a neutron and then undergoing a fission reaction
• U-235 and Pu-239 do undergo induced fission reactions
• U-238 does not directly undergo an induced fission reaction
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The Fission of U-235
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Nuclear Chain Reactions
• The process in which neutrons released in one fission reaction causes at least one additional nucleus to undergo fission.
• The number of fissions doubles generation if each neutron releases 2 more neutrons
• In 10 generations there will be 1024 fissions and in 80 generations about 6 x 1023 (a mole)
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Nuclear Chain Reaction
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Critical Mass
• If the amount of fissile material is small, many of the neutrons will not strike another nucleus and the chain reaction will stop
• The critical mass is the amount of fissile material necessary for a chain reaction to become self-sustaining.
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Nuclear Chain Reactions
• An uncontrolled chain reaction is used in nuclear weapons
• A controlled chain reaction can be used for nuclear power generation
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Uncontrolled Chain Reactions
The Atomic Bomb
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Little Boy Bomb
• The atomic bomb dropped on Hiroshima on August 6, 1945
• Little boy was a U-235 gun-type bomb
• Between 80,000 and 140,000 people were killed instantly
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The Gun-Type Bomb
• The two subcritical masses of U-235 are brought together with an explosive charge creating a sample that exceeds the critical mass.
• The initiator introduces a burst of neutrons causing the chain reaction to begin
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Fat Man
• A plutonium implosion-type bomb
• Dropped on Nagasaki on August 9, 1945
• 74,000 were killed and 75,000 severely injured
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Plutonium Implosion-Type Bomb
• Explosive charges compress a sphere of plutonium quickly to a density sufficient to exceed the critical mass
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Controlled Nuclear Fission
• Maintaining a sustained, controlled reaction requires that only one of the neutrons produced in the fission be allowed to strike another uranium nucleus
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Controlled Nuclear Fission
• If the ratio of produced neutrons to used neutrons is less than one, the reaction will not be sustained.
• If this ratio is greater than one, the reaction will become uncontrolled resulting in an explosion.
• A neutron-absorbing material such as graphite can be used to control the chain reaction.
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From Steam To Electricity
• Different fuels can be used to generate the heat energy needed to produce the steam– Combustion of fossil fuels
– Nuclear fission
– Nuclear fusion
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Types of Fission Reactors
• Light Water Reactors (LWR) – Pressurized-light water reactors (PWR)– Boiling water reactors (BWR)
• Breeder reactors
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Light Water Reactors
• Most popular reactors in U.S.
• Use normal water as a coolant and moderator
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Pressurized Water Reactor
• The PWR has 3 separate cooling systems.• Only 1 should have radioactivity
– the Reactor Coolant System
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Inside Containment Structure
• Fuel Rods contain U (3-5% enriched in U-235) or Pu in alloy or oxide form
• Control rods (Cd or graphite) absorb neutrons. Rods can be raised or lowered to change rate of reaction
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U-235 Enrichment
• Naturally occurring uranium is 99.3% non fissile U-238 & 0.7% fissile U-235
• In light water reactors, this amount of U-235 is not sufficient to sustain the chain reaction
• The uranium is processed to increase the amount of U-235 in the mixture
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Graham’s Law of Diffusion & Effusion
• Diffusion- rate at which two gases mix
• Effusion- rate at which a gas escapes through a pinhole into a vacuum
• In both cases the rate is inversely proportional to the square root of the MW of the gas
• Rate 1/(MW)0.5
• For 2 gases the rate of effusion of the lighter is:Rate = (MWheavy/MWlight)0.5
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U-235 Enrichment• Rate U-235/238= (352/349)0.5= 1.004• The enrichment after n diffusion barriers is
(1.004)n
• Minimum amount of U-235 needed in LWR is 2.1% (3x more concentrated than in natural form)
• (1.004)263=3 or 263 diffusion stages needed • Enrichment is an expensive process• Large amount of energy is needed to push the
UF6 through so many barriers
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Inside Containment Structure
• Coolant performs 2 functions– keeps reactor core from getting too hot
– transfers heat which drives turbines
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Water as Coolant
• Light Water Reactor (LWR)– uses ordinary water– needs enriched uranium fuel– common in U.S.– 80% of world’s reactors
• Heavy Water Reactor (HWR)– uses D2O
– can use natural uranium– common in Canada and Great Britain– 10% of world’s reactors
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Water As Coolant
• Pressurized Water Reactors – uses a heat exchanger– keeps water that passes the reactor core in a
closed loop– steam in turbines never touches fuel rods
• Boiling Water Reactors – no heat exchanger– water from reactor core goes to turbines– simpler design/greater contamination risk
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PWR vs. BWR
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The Moderator
• The moderator is necessary to slow down neutrons (probability of causing a fission is increased with slow moving neutrons)
• Light water will capture some neutrons so enriched enriched fuel is needed
• Heavy water captures far fewer neutrons so don’t need enriched fuel
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Breeder Reactors
• Generate more fissionable material than they consume
• Fuel U-238, U-235 & P-239• No moderator is used
– Fast neutrons are captured by non fissionable U-238 to produce U-239
– U-239 decays to fissile Pu-239
• Coolant is liquid sodium metal• None in U.S.
– France, Great Britain, Russia
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Breeder Reactor Processes
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Breeder Reactors
• Advantages– creates fissionable material by transforming U-
238 into Pu-239– Fuel less costly
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Breeder Reactors• Disadvantages
– no moderator (if something goes wrong, it will happen quicker)
– liquid sodium coolant is extremely corrosive and dangerous
– Plutonium has a critical mass 50% less than uranium
• more widely used for weapons
• more actively sought by terrorists
– Fuel rods require periodic reprocessing to remove contaminants resulting from nuclear reactions (cost consideration)