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Chapter 45. Applications of Nuclear Physics. Processes of Nuclear Energy. Fission A nucleus of large mass number splits into two smaller nuclei. Fusion Two light nuclei fuse to form a heavier nucleus. Large amounts of energy are released in both cases. Introduction.
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Chapter 45 Applications of Nuclear Physics
Processes of Nuclear Energy • Fission • A nucleus of large mass number splits into two smaller nuclei. • Fusion • Two light nuclei fuse to form a heavier nucleus. • Large amounts of energy are released in both cases. Introduction
Interactions Involving Neutrons • Because of their charge neutrality, neutrons are not subject to Coulomb forces. • As a result, they do not interact electrically with electrons or the nucleus. • Neutrons can easily penetrate deep into an atom and collide with the nucleus. Section 45.1
Fast Neutrons • A fast neutron has energy greater than approximately 1 MeV. • During its many collisions when traveling through matter, the neutron gives up some of its kinetic energy. • For fast neutrons in some materials, elastic collisions dominate. • These materials are called moderators since they moderate the originally energetic neutrons very efficiently. • Moderator nuclei should be of low mass so that a large amount of kinetic energy is transferred to them in elastic collisions. • Materials such as paraffin and water are good moderators for neutrons. Section 45.1
Thermal Neutrons • Most neutrons bombarding a moderator will become thermal neutrons. • They are in thermal equilibrium with the moderator material. • Their average kinetic energy at room temperature is about 0.04 eV. • This corresponds to a neutron root-mean-square speed of about 2 800 m/s. • Thermal neutrons have a distribution of speeds. Section 45.1
Neutron Capture • Once the energy of a neutron is sufficiently low, there is a high probability that it will be captured by a nucleus. • The neutron capture equation can be written as • The excited state lasts for a very short time. • The product nucleus is generally radioactive and decays by beta emission. Section 45.1
Nuclear Fission • A heavy nucleus splits into two smaller nuclei. • Fission is initiated when a heavy nucleus captures a thermal neutron. • The total mass of the daughter nuclei is less than the original mass of the parent nucleus. • This difference in mass is called the mass defect. • Multiplying the mass defect by c2 gives the numerical value of the released energy. • This energy is in the form of kinetic energy associated with the motion of the neutrons and the daughter nuclei after the fission event. Section 45.2
Short History of Fission • First observed in 1938 by Otto Hahn and Fritz Strassman following basic studies by Fermi. • Bombarding uranium with neutrons produced barium and lanthanum. • Lise Meitner and Otto Frisch soon explained what had happened. • After absorbing a neutron, the uranium nucleus had split into two nearly equal fragments. • About 200 MeV of energy was released. Section 45.2
Fission Equation: 235U • Fission of 235U by a thermal neutron • 236U* is an intermediate, excited state that exists for about 10-12 s before splitting. • X and Y are called fission fragments. • Many combinations of X and Y satisfy the requirements of conservation of energy and charge. Section 45.2
Fission Example: 235U • A typical fission reaction for uranium is Section 45.2
Distribution of Fission Products • The most probable products have mass numbers A 95 and A 140. • There are also 2 to 3 neutrons released per event. Section 45.2
Energy in a Fission Process • Binding energy for heavy nuclei is about 7.2 MeV per nucleon. • Binding energy for intermediate nuclei is about 8.2 MeV per nucleon. • An estimate of the energy released • Releases about 1 MeV per nucleon • 8.2 MeV – 7.2 MeV • Assume a total of 235 nucleons • Total energy released is about 235 MeV • This is the disintegration energy, Q • This is very large compared to the amount of energy released in chemical processes. Section 45.2
Chain Reaction • Neutrons are emitted when 235U undergoes fission. • An average of 2.5 neutrons • These neutrons are then available to trigger fission in other nuclei. • This process is called a chain reaction. • If uncontrolled, a violent explosion can occur. • When controlled, the energy can be put to constructive use. Section 45.3
Chain Reaction – Diagram Section 45.3
Enrico Fermi • 1901 – 1954 • Italian physicist • Nobel Prize in 1938 for producing transuranic elements by neutron irradiation and for his discovery of nuclear reactions brought about by thermal neutrons • Other contributions include theory of beta decay, free-electron theory of metal, development of world’s first fission reactor (1942) Section 45.3
Nuclear Reactor • A nuclear reactor is a system designed to maintain a self-sustained chain reaction. • The reproduction constant K is defined as the average number of neutrons from each fission event that will cause another fission event. • The average value of K from uranium fission is 2.5. • In practice, K is less than this • A self-sustained reaction has K = 1 Section 45.3
K Values • When K = 1, the reactor is said to be critical. • The chain reaction is self-sustaining. • When K < 1, the reactor is said to be subcritical. • The reaction dies out. • When K > 1, the reactor is said to be supercritical. • A run-away chain reaction occurs. Section 45.3
Moderator • The moderator slows the neutrons. • The slower neutrons are more likely to react with 235U than 238U. • The probability of neutron capture by 238U is high when the neutrons have high kinetic energies. • Conversely, the probability of capture is low when the neutrons have low kinetic energies. • The slowing of the neutrons by the moderator makes them available for reactions with 235U while decreasing their chances of being captured by 238U. Section 45.3
Reactor Fuel • Most reactors today use uranium as fuel. • Naturally occurring uranium is 99.3% 238U and 0.7% 235U • 238U almost never fissions • It tends to absorb neutrons producing neptunium and plutonium. • Fuels are generally enriched to at least a few percent 235U. Section 45.3
Pressurized Water Reactor – Diagram Section 45.3
Pressurized Water Reactor – Notes • This type of reactor is the most common in use in electric power plants in the US. • Fission events in the uranium in the fuel rods raise the temperature of the water contained in the primary loop. • The primary system is a closed system. • This water is maintained at a high pressure to keep it from boiling. • This water is also used as the moderator to slow down the neutrons. Section 45.3
Pressurized Water Reactor – Notes, cont. • The hot water is pumped through a heat exchanger. • The heat is transferred by conduction to the water contained in a secondary system. • This water is converted into steam. • The steam is used to drive a turbine-generator to create electric power. Section 45.3
Pressurized Water Reactor – Notes, final • The water in the secondary system is isolated from the water in the primary system. • This prevents contamination of the secondary water and steam by the radioactive nuclei in the core. • A fraction of the neutrons produced in fission leak out before inducing other fission events. • An optimal surface area-to-volume ratio of the fuel elements is a critical design feature. Section 45.3
Basic Design of a Reactor Core • Fuel elements consist of enriched uranium. • The moderator material helps to slow down the neutrons. • The control rods absorb neutrons. • All of these are surrounded by a radiation shield. Section 45.3 Section 45.3
Control Rods • To control the power level, control rods are inserted into the reactor core. • These rods are made of materials that are very efficient in absorbing neutrons. • Cadmium is an example • By adjusting the number and position of the control rods in the reactor core, the K value can be varied and any power level can be achieved. • The power level must be within the design of the reactor. Section 45.3
Reactor Safety – Containment • Radiation exposure, and its potential health risks, are controlled by three levels of containment: • Reactor vessel • Contains the fuel and radioactive fission products • Reactor building • Acts as a second containment structure should the reactor vessel rupture • Prevents radioactive material from contaminating the environment • Location • Reactor facilities are in remote locations Section 45.3
Reactor Safety – Radioactive Materials • Disposal of waste material • Waste material contains long-lived, highly radioactive isotopes. • Must be stored over long periods in ways that protect the environment • At present, the most promising solution seems to be sealing the waste in waterproof containers and burying them in deep geological repositories. • Transportation of fuel and wastes • Accidents during transportation could expose the public to harmful levels of radiation. • Department of Energy requires crash tests and manufacturers must demonstrate that their containers will not rupture during high speed collisions. Section 45.3
Nuclear Fusion • Nuclear fusion occurs when two light nuclei combine to form a heavier nucleus. • The mass of the final nucleus is less than the masses of the original nuclei. • This loss of mass is accompanied by a release of energy. Section 45.4
Fusion: Proton-Proton Cycle • The proton-proton cycle is a series of three nuclear reactions believed to operate in the Sun. • Energy liberated is primarily in the form of gamma rays, positrons and neutrinos. • All of the reactions in the proton-proton cycle are exothermic. • An overview of the cycle is that four protons combine to form an alpha particle, positrons, gamma rays and neutrinos. Section 45.4
Fusion in the Sun • These reactions occur in the core of a star and are responsible for the energy released by the stars. • High temperatures are required to drive these reactions. • Therefore, they are known as thermonuclear fusion reactions. Section 45.4
Advantages of a Fusion Reactor • Inexpensive fuel source • Water is the ultimate fuel source. • If deuterium is used as fuel, 0.12 g of it can be extracted from 1 gal of water for about 4 cents. • Comparatively few radioactive by-products are formed. Section 45.4
Considerations for a Fusion Reactor • The proton-proton cycle is not feasible for a fusion reactor. • The high temperature and density required are not suitable for a fusion reactor. • The most promising reactions involve deuterium and tritium. Section 45.4
Considerations for a Fusion Reactor, cont. • Tritium is radioactive and must be produced artificially. • The Coulomb repulsion between two charged nuclei must be overcome before they can fuse. • A major problem in obtaining energy from fusion reactions. Section 45.4
Potential Energy Function • The potential energy is positive in the region r > R, where the Coulomb repulsive force dominates. • It is negative where the nuclear force dominates. • The problem is to give the nuclei enough kinetic energy to overcome this repulsive force. • Can be accomplished raising the temperature of the fuel to approximately 108 K. • At this temperature, the atoms are ionized and the system contains a collection of electrons and nuclei, referred to as a plasma. Section 45.4
Critical Ignition Temperature • The temperature at which the power generation rate in any fusion reaction exceeds the lost rate is called the critical ignition temperature, Tignit. • The intersections of the Pgen lines with the Plost line give the Tignit. Section 45.4
Requirements for Successful Thermonuclear Reactor • High temperature ~ 108 K • Needed to give nuclei enough energy to overcome Coulomb forces • Plasma ion density, n • The number of ions present • Plasma confinement time, • The time interval during which energy injected into the plasma remains in the plasma. Section 45.4
Lawson’s Criteria • Lawson’s criteria states that a net power output in a fusion reactor is possible under the following conditions. • n≥ 1014 s/cm3 for deuterium-tritium • n≥ 1016 s/cm3 for deuterium-deuterium • These are the minima on the curves. Section 45.4
Requirements, Summary • The plasma temperature must be very high. • To meet Lawson’s criterion, the product nt must be large. • For a given value of n, the probability of fusion between two particles increases as t increases. • For a given value of t, the collision rate increases as n increases. • Confinement is still a problem. Section 45.4
Confinement Techniques • Magnetic confinement • Uses magnetic fields to confine the plasma • Inertial confinement • Particles’ inertia keeps them confined very close to their initial positions. Section 45.4
Magnetic Confinement • One magnetic confinement device is called a tokamak. • Two magnetic fields confine the plasma inside the donut. • A strong magnetic field is produced in the windings. • A weak magnetic field is produced by the toroidal current. • The field lines are helical, they spiral around the plasma, and prevent it from touching the wall of the vacuum chamber. Section 45.4
Fusion Reactors Using Magnetic Confinement • TFTR – Tokamak Fusion Test Reactor • Close to values required by Lawson criterion • JET – Joint European Torus • Reaction rates of 6 x 1017 D-T fusions per second were reached • NSTX – National Spherical Torus Experiment • Produces a spherical plasma with a hole in the center • Is able to confine the plasma with a high pressure • ITER – International Thermonuclear Experimental Reactor • An international collaboration involving four major fusion programs is working on building this reactor. • It will address remaining technological and scientific issues concerning the feasibility of fusion power. • Fusion operation is expected to begin in 2018. Section 45.4
Inertial Confinement • Uses a D-T target that has a very high particle density • Confinement time is very short. • Therefore, because of their own inertia, the particles do not have a chance to move from their initial positions. • Lawson’s criterion can be satisfied by combining high particle density with a short confinement time. Section 45.4
Laser Fusion • Laser fusion is the most common form of inertial confinement. • A small D-T pellet is struck simultaneously by several focused, high intensity laser beams. • This large input energy causes the target surface to evaporate. • The third law reaction causes an inward compression shock wave. • This increases the temperature. Section 45.4
Fusion Reactors Using Inertial Confinement • Omega facility • University of Rochester (NY) • Focuses 24 laser beams on the target • National Ignition Facility • Lawrence Livermore National Lab (CA) • Construction was completed in early 2009 • Will include 192 laser beams focused on D-T pellets • The lasers were fired in March 2009 and broke the megajoule record for lasers. • They delivered 1.1 MJ to a target • Fusion ignition tests are planned for 2010. Section 45.4
Fusion Reactor Design – Energy • In the D-T reaction, the alpha particle carries 20% of the energy and the neutron carries 80%. • The neutrons are about 14 MeV. • The alpha particles are primarily absorbed by the plasma, increasing the plasma’s temperature. • The neutrons are absorbed by the surrounding blanket of material where their energy is extracted and used to generate electric power.
Fusion Reactor Design, cont. • One scheme is to use molten lithium to capture the neutrons. • The lithium goes to a heat-exchange loop and eventually produces steam to drive turbines. Section 45.4
Fusion Reactor Design, Diagram Section 45.4
Some Advantages of Fusion • Low cost and abundance of fuel • Deuterium • Impossibility of runaway accidents • Decreased radiation hazards Section 45.4
Some Anticipated Problems with Fusion • Scarcity of lithium • Limited supply of helium • Helium is needed for cooling the superconducting magnets used to produce the confinement fields. • Structural damage and induced radiation from the neutron bombardment Section 45.4
Radiation Damage • Radiation absorbed by matter can cause damage. • The degree and type of damage depend on many factors. • Type and energy of the radiation • Properties of the matter Section 45.5