Nuclear Fission & Fusion

Similar documents
40 Nuclear Fission and Fusion. Nuclear fission and nuclear fusion reactions release huge amounts of energy.

Nuclear Fission. Conceptual Physics 11 th Edition. Nuclear Fission. Nuclear Fission. Nuclear Fission. This lecture will help you understand:

Nuclear Reactions and E = mc 2. L 38 Modern Physics [4] Hazards of radiation. Radiation sickness. Biological effects of nuclear radiation

Radioactivity. L 38 Modern Physics [4] Hazards of radiation. Nuclear Reactions and E = mc 2 Einstein: a little mass goes a long way

Matter and Energy. Previous studies have taught us that matter and energy cannot be created nor destroyed We balance equations to obey this law.

Fission & Fusion Movie

Chapter 18. Nuclear Chemistry


Term 3 Week 2 Nuclear Fusion & Nuclear Fission

Nuclear Energy Learning Outcomes

Nuclear Energy Learning Outcomes. Nuclear Fission. Chain Reaction

NUCLEI. Atomic mass unit

Chapter 10 Section 4 Notes

The Physics of Nuclear Reactors. Heather King Physics 420

FUSION NEUTRON DEUTERIUM HELIUM TRITIUM.

RADIOACTIVITY & HALF-LIFE Part 3

Step 2: Calculate the total amount of U-238 present at time=0. Step 4: Calculate the rate constant for the decay process.

Nuclear 2. Fission and Fusion

Chapter 18 Nuclear Chemistry

Chapter 12: Nuclear Reaction

Nuclear Reactions A Z. Radioactivity, Spontaneous Decay: Nuclear Reaction, Induced Process: x + X Y + y + Q Q > 0. Exothermic Endothermic

Unpressurized steam reactor. Controlled Fission Reactors. The Moderator. Global energy production 2000

Forces and Nuclear Processes

Nuclear Fusion 1 of 24 Boardworks Ltd 2011

NUCLEAR ENERGY! DAY 1: (RADIATION, FISSION, FUSION)

Nuclear Physics and Nuclear Reactions

L 36 Atomic and Nuclear Physics-4. Radioactivity. Nuclear reactions: E = mc 2. Hazards of radiation. Biological effects of nuclear radiation

PHYS:1200 LECTURE 36 ATOMIC AND NUCLEAR PHYSICS (4)

Chapter 22. Preview. Objectives Properties of the Nucleus Nuclear Stability Binding Energy Sample Problem. Section 1 The Nucleus

L 36 Modern Physics :006 FINAL EXAM. Nuclear reactions: E = mc 2. Radioactivity. Hazards of radiation. Biological effects of nuclear radiation

2 Energy from the Nucleus

Atomic and Nuclear Physics. Topic 7.3 Nuclear Reactions

Fission and Fusion Book pg cgrahamphysics.com 2016

10.4 Fission and Fusion

By Tim, John, Shane, Owen

Aim: What are the two types of Nuclear. Reactions? Do Now: 1. Get into your groups and compare your answers to your homework.

Lecture 14, 8/9/2017. Nuclear Reactions and the Transmutation of Elements Nuclear Fission; Nuclear Reactors Nuclear Fusion

(nuclear) reactor 1. (average) time taken for number of nuclei to halve or (average) time taken for count-rate / activity to halve

NUCLEAR PHYSICS: solutions to higher level questions

DEVIL PHYSICS THE BADDEST CLASS ON CAMPUS IB PHYSICS

Nuclear Physics Questions. 1. What particles make up the nucleus? What is the general term for them? What are those particles composed of?

Preview. Subatomic Physics Section 1. Section 1 The Nucleus. Section 2 Nuclear Decay. Section 3 Nuclear Reactions. Section 4 Particle Physics

Chemistry: The Central Science. Chapter 21: Nuclear Chemistry

NJCTL.org 2015 AP Physics 2 Nuclear Physics

Radioactivity & Nuclear. Chemistry. Mr. Matthew Totaro Legacy High School. Chemistry

PhysicsAndMathsTutor.com 1

Radioactivity pp Topic 9: Nuclear Physics Ch. 10. Radioactivity. Radioactivity

Nuclear fission and fusion are processes that involve extremely large amounts of energy.

The Atomic Nucleus & Radioactive Decay. Major Constituents of an Atom 4/28/2016. Student Learning Outcomes. Analyze radioactive decay and its results

Nuclear Physics 2. D. atomic energy levels. (1) D. scattered back along the original direction. (1)

Special!Area!of!Study!1! Energy!from!the!nucleus!

Write down the nuclear equation that represents the decay of neptunium 239 into plutonium 239.

General Physics (PHY 2140)

Recap I Lecture 41 Matthias Liepe, 2012

Nuclear Physics. AP Physics B

A is called the mass number gives, roughly, the mass of the nucleus or atom in atomic mass units = amu = u

c) O-16 d) Pu An unstable nucleus emits. a) Atoms b) Electricity c) Plasma d) Radiation 3. Many of uranium are radioactive. a) Ions b) Isomers

LECTURE 25 NUCLEAR STRUCTURE AND STABILITY. Instructor: Kazumi Tolich

11.5 Nuclear Reactions: Fusion

Chapter 10. Answers to examination-style questions. Answers Marks Examiner s tips. 1 (a) (i) 238. (ii) β particle(s) 1 Electron antineutrinos 1

Science 10: Radioactivity! Comparing Fission and Fusion Notes (Ch 11)

Radioactivity is the spontaneous disintegration of nuclei. The first radioactive. elements discovered were the heavy atoms thorium and uranium.

Uranium has two natural isotopes, uranium-235 and uranium-238. Use the correct answer from the box to complete the sentence.

Nuclear Energy. Nuclear Structure and Radioactivity

Nuclear Chemistry Review Packet

Nuclear Chemistry. Nuclear Terminology

Science 10 Radioactivity Review v3

Name: New Document 1. Class: Date: 54 minutes. Time: 54 marks. Marks: Comments: Page 1 of 22

Lecture 5 Nuclear Reactions

There are 82 protons in a lead nucleus. Why doesn t the lead nucleus burst apart?

Nuclear Chemistry. The nuclei of some unstable isotopes change by releasing energy and particles, collectively known as radiation

Nuclear Chemistry. Transmutations and the Creation of Elements

Alta Chemistry CHAPTER 25. Nuclear Chemistry: Radiation, Radioactivity & its Applications

DEVIL PHYSICS THE BADDEST CLASS ON CAMPUS IB PHYSICS

Relative abundances of carbon isotopes in our atmosphere are:

turbine (a) (i) Which part of the power station provides thermal (heat) energy from a chain reaction?

Chapter 7 Review. Block: Date:

Unit 3: Chemistry in Society Nuclear Chemistry Summary Notes

One nucleus splits into two smaller nuclei and typically a few neutrons by the bombardment of a neutron. U-235 is the only naturally occurring

Lecture Outlines Chapter 32. Physics, 3 rd Edition James S. Walker

Chapter 16 Nuclear Chemistry. An Introduction to Chemistry by Mark Bishop

Chapter 10 - Nuclear Physics

Mechanical Engineering Introduction to Nuclear Engineering /12

Nuclear forces and Radioactivity. Two forces are at work inside the nucleus of an atom

Chapter 32 Applied Nucleonics

Chapter 21. Preview. Lesson Starter Objectives Mass Defect and Nuclear Stability Nucleons and Nuclear Stability Nuclear Reactions

Ch Radioactivity. Henry Becquerel, using U-238, discovered the radioactive nature of elements in 1896.

Energy from the Nucleus

MockTime.com. Ans: (b) Q6. Curie is a unit of [1989] (a) energy of gamma-rays (b) half-life (c) radioactivity (d) intensity of gamma-rays Ans: (c)

Lecture PowerPoints. Chapter 31 Physics: Principles with Applications, 7th edition Giancoli

Nuclear power plants can generate large amounts of electricity.

Introducing nuclear fission The Fizzics Organization

Nobel prizes in nuclear and reactor physics. Szabolcs Czifrus Institute of Nuclear Techniques BME

This Week. Production, Usage and Distribution of Energy. 8/4/2017 Physics 214 Fall

This Week. 3/23/2017 Physics 214 Summer

Lecture Presentation. Chapter 21. Nuclear Chemistry. James F. Kirby Quinnipiac University Hamden, CT Pearson Education, Inc.

THE NUCLEUS OF AN ATOM

Nuclear Chemistry. Chapter 24

Chapter 22 - Nuclear Chemistry

Atomic Structure & Nuclear Chemistry Unit 3 Notes

Transcription:

Nuclear Fission & Fusion 1

Nuclear Fission 2

There is a delicate balance between nuclear attraction and electrical repulsion between protons in the nucleus. Nuclear Fission If the uranium nucleus is stretched into an elongated shape, the electrical forces may push it into an even more elongated shape. 3

Nuclear Fission Nuclear forces yield to electrical ones and the nucleus separates. 4

Nuclear Fission 5

Nuclear Fission 6

Nuclear Fission A chain reaction is a self-sustaining reaction in which the products of one reaction event stimulate further reaction events. 7

Nuclear Fission Typical fission reaction > 200,000,000 ev Explosion of 1 TNT molecule ~ 30 ev 1 ev = 1.6 x 10-19 J 8

Nuclear Fission The combined mass of the fission fragments and neutrons produced in fission is less than the mass of the original uranium nucleus plus the original neutron that triggered the fission! 9

Nuclear Fission A fission reaction can be self-sustaining! Each new neutron can cause the fissioning of two or three other atomic nuclei, releasing more energy and from four to nine more neutrons. 10

Nuclear Fission Why do chain reactions not occur in naturally occurring uranium deposits? Naturally occurring uranium is too impure to undergo a chain reaction spontaneously. 11

Nuclear Fission 12

Nuclear Fission 13

Nuclear Fission 14

Nuclear Fission Critical Mass is the amount of mass for which each fission event produces, on average, one additional fission event. 15

Nuclear Fission 16

Nuclear Fission The difficulty in bomb making is separating enough U-235 from all the U-238 in uranium ore. 17

Nuclear Fission The vast quantities of energy stored in an atomic nucleus can be harnessed to provide energy for daily life. This is Fission Power. 18

Fission Power All energy producing power plants convert water to steam that drives turbines to generate electricity. Various fuels are used: coal, oil, gas, and now, fissionable isotopes like uranium. 19

The fissioning of U-235 requires that the stimulating neutrons have the proper speeds. Fission Power 20

Fission Power This is similar to the selective absorption of various frequencies of light. Just as various elements absorb and reflect light differently, various isotopes of the same element can have quite different nuclear properties and absorb neutrons differently. 21

Fission Power Only relatively slow neutrons will initiate fission in these two isotopes. 22

Fission Power Enrico Fermi led the construction of the first nuclear reactor or atomic pile, in a squash court underneath the grandstands of the University of Chicago's Stagg Field. 23

Fission Power 24

Fission Power 1 kg of uranium fuel (a chunk smaller than a baseball) yields more energy than 30 freight car loads of coal! About 20% of electric energy in the US is generated by nuclear fission reactors. 25

Benefits of Fission Power 1. Plentiful electricity 2. Conservation of the many billions of tons of coal, oil and natural gas that every year are literally converted to heat and smoke 3. Elimination of megatons of sulfur oxide and other poison, as well as greenhouse gas Carbon Dioxide that are released into the air each year by the burning of these fossil fuels. 26

Downside of Fission Reactors Generation of radioactive waste products. 27

Plutonium & Breeding in 1930, what seemed to be a planet beyond Neptune was discovered and named Pluto In 1846, the planet Neptune was discovered beyond Uranus 28

Plutonium & Breeding When a U-238 nucleus absorbs a neutron, no fission occurs. 29

Plutonium & Breeding With a half-life of 24 minutes, it emits a beta particle and becomes an isotope of the first synthetic element beyond uranium the transuranic element called neptunium. 30

Plutonium & Breeding Np-239 is a beta emitter and soon emits a beta particle and becomes an isotope of plutonium, specifically Pu-239. 31

Plutonium & Breeding The nucleus of Pu-239, like U-235, will undergo fission when it captures a neutron. Pu-239 is even more fissionable than U-235. 32

Plutonium & Breeding Plutonium is chemically toxic in the same sense as are lead and arsenic. It attacks the nervous system and can cause paralysis; death can follow if the dose is sufficiently large. Plutonium in any form, is radioactively toxic to humans and other animals. It is more toxic than uranium, although less toxic than radium. 33

Plutonium & Breeding A remarkable feature of fission power is the breeding of plutonium from nonfissionable U-238. 34

Plutonium & Breeding 35

Plutonium & Breeding Some breeding occurs in all fission reactors, but a breeder reactor is specifically designed to breed more fissionable fuel than is put into it. 36

Mass-Energy Equivalence E = mc 2 37

Mass-Energy Equivalence The more energy that is stored in a particle, the greater is the mass of that particle. The mass of a nucleus is not simply the sum of the masses of the individual nucleons that compose it! 38

Mass-Energy Equivalence Think of the amount of force required to pull a nucleon out of the nucleus through a sufficient distance to overcome the attractive strong nuclear force. Enormous work would be required! 39

Mass-Energy Equivalence Mass Spectrometer 40

Mass-Energy Equivalence C-12 mass per nucleon 1.00000 amu Mass of proton + electron 1.007825 amu Mass of lone neutron 1.00867 amu 41

Mass-Energy Equivalence (Number of Protons) 42

Mass-Energy Equivalence Average mass per nucleon = Total mass of atom -------------------------------------- Number of nucleons in nucleus 43

Mass-Energy Equivalence 44

Mass-Energy Equivalence It turns out that the mass of a nucleus is NOT equal to the sum of the masses of its parts! So where is the missing mass? 45

Mass-Energy Equivalence The missing mass come out as ENERGY! And lots of it! 46

Mass-Energy Equivalence 47

Mass-Energy Equivalence All nuclear power today is by way of nuclear fission. 48

Nuclear Fusion Fusion is the opposite process of fission. Fusion is when nuclei of light atoms are fused to form nuclei of heavier atoms again with the release of much energy! 49

Accelerate a proton at high energy toward a target that contains other protons. Nuclear Fusion But that involves just a few protons and releases very little energy. 50

Nuclear Fusion Large Hadron Collider 51

Nuclear Fusion Fusion occurs in the sun s interior due to its environment of enormous heat and gravitational contraction. Fusion in the sun is called thermonuclear fusion because it is brought about by high temperatures. 52

Nuclear Fusion Prior to the development of the fission bomb, the temperatures required to overcome mutual proton repulsion and initiate nuclear fusion on Earth were unattainable. 53

Nuclear Fusion Nothing less energetic than a fission bomb can ignite a thermonuclear bomb! 54

Nuclear Fusion 55

Nuclear Fusion Mass per Nucleon versus Atomic Number 56

Nuclear Fusion Mass per Nucleon versus Atomic Number 57

Nuclear Fusion Deuterium Deuterium He-3 58

Nuclear Fusion Deuterium Tritium He-4 59

Nuclear Fusion Both fission and fusion reactions can only occur if there are two or more products of the reaction to carry away ENERGY! 60

Nuclear Fusion Nuclear energy is released when atoms split apart. Now we learn that nuclear energy is released when atoms combine. Is this a contradiction? How can energy be released by opposite processes? 61

Controlled Fusion 62

Controlled Fusion 63

Controlled Fusion Mass per Nucleon versus Atomic Number If we want energy out of the reaction, we should always move downhill. Fuse light elements or fission heavy elements. In both cases, decreased mass per nucleon is the name of the game. 64

Controlled Fusion Fusion processes in stars cease at elements close to iron, where the energy graph starts to slope upward. Stars are cooled at this stage, fusion ceases. 65

Controlled Fusion OR Which releases more energy? 66

Controlled Fusion + 200 MeV OR + 17.6 MeV 67

Controlled Fusion 68

Controlled Fusion 69

Controlled Fusion 70

Controlled Fusion 71

Controlled Fusion One final question: Sometimes pairs of iron nuclei are fused in stellar cores. Does this fusion further heat the star or cool it? 72

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback