Chem 481 Lecture Material 1/30/09

Similar documents
CHAPTER 7 TEST REVIEW

Particles. Constituents of the atom


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

Types of radiation resulting from radioactive decay can be summarized in a simple chart. Only X-rays, Auger electrons and internal conversion

Particle Physics Outline the concepts of particle production and annihilation and apply the conservation laws to these processes.

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

General Physics (PHY 2140)

Alpha Decay. Decay alpha particles are monoenergetic. Nuclides with A>150 are unstable against alpha decay. E α = Q (1-4/A)

Introduction to Nuclear Science

Basic science. Atomic structure. Electrons. The Rutherford-Bohr model of an atom. Electron shells. Types of Electrons. Describing an Atom

Fundamental Forces. Range Carrier Observed? Strength. Gravity Infinite Graviton No. Weak 10-6 Nuclear W+ W- Z Yes (1983)

Radioactivity and energy levels

Unit 8.1 Nuclear Chemistry - Nuclear Reactions. Review. Radioactivity. State College Area School District Teacher: Van Der Sluys

α particles, β particles, and γ rays. Measurements of the energy of the nuclear

Sources of Radiation

2007 Fall Nuc Med Physics Lectures

α particles, β particles, and γ rays. Measurements of the energy of the nuclear

Modern Physics: Standard Model of Particle Physics (Invited Lecture)

Some nuclei are unstable Become stable by ejecting excess energy and often a particle in the process Types of radiation particle - particle

Introduction to Nuclear Science

LECTURE 26 RADIATION AND RADIOACTIVITY. Instructor: Kazumi Tolich

Chapter 3 Radioactivity

General Physics (PHY 2140)

Chapter 30 Nuclear Physics and Radioactivity

Decay Mechanisms. The laws of conservation of charge and of nucleons require that for alpha decay, He + Q 3.1

General and Inorganic Chemistry I.

Thursday, April 23, 15. Nuclear Physics

DEVIL PHYSICS THE BADDEST CLASS ON CAMPUS IB PHYSICS

Physics 4213/5213 Lecture 1

Baryons, mesons and leptons are affected by particle interactions. Write an account of these interactions. Your account should:

Lecture 1. Introduction to Nuclear Science

LECTURE 23 NUCLEI. Instructor: Kazumi Tolich

Chapter Three (Nuclear Radiation)

Conceptual Physics Nuclear Physics

Instead, the probability to find an electron is given by a 3D standing wave.

PHY-105: Introduction to Particle and Nuclear Physics

Nuclear Decays. Alpha Decay

Chapter 44. Nuclear Structure

Introduction to Modern Physics Problems from previous Exams 3

Chemistry 19 Prep Test - Nuclear Processes

Nuclear Spectroscopy: Radioactivity and Half Life

FACTS WHY? C. Alpha Decay Probability 1. Energetics: Q α positive for all A>140 nuclei

NOTES: 25.2 Nuclear Stability and Radioactive Decay

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

2007 Section A of examination problems on Nuclei and Particles

Chapter 18: Radioactivity And Nuclear Transformation. Presented by Mingxiong Huang, Ph.D.,

Phys102 Lecture 29, 30, 31 Nuclear Physics and Radioactivity

Chapter from the Internet course SK180N Modern Physics

Lecture 33 Chapter 22, Sections 1-2 Nuclear Stability and Decay. Energy Barriers Types of Decay Nuclear Decay Kinetics

cgrahamphysics.com Particles that mediate force Book pg Exchange particles

Overview. The quest of Particle Physics research is to understand the fundamental particles of nature and their interactions.

Alpha decay. Introduction to Nuclear Science. Simon Fraser University Spring NUCS 342 February 21, 2011

Nuclear Physics. Chapter 43. PowerPoint Lectures for University Physics, Thirteenth Edition Hugh D. Young and Roger A. Freedman

Supplement 1: Beta Decay

FUNDAMENTAL PARTICLES CLASSIFICATION! BOSONS! QUARKS! FERMIONS! Gauge Bosons! Fermions! Strange and Charm! Top and Bottom! Up and Down!

Introduction to Nuclear Physics and Nuclear Decay

Nice Try. Introduction: Development of Nuclear Physics 20/08/2010. Nuclear Binding, Radioactivity. SPH4UI Physics

NJCTL.org 2015 AP Physics 2 Nuclear Physics

A. Incorrect! Do not confuse Nucleus, Neutron and Nucleon. B. Incorrect! Nucleon is the name given to the two particles that make up the nucleus.

The number of protons in the nucleus is known as the atomic number Z, and determines the chemical properties of the element.

Nuclear Physics Part 2A: Radioactive Decays

Introduction to Nuclear Reactor Physics

Option 212: UNIT 2 Elementary Particles

Units and Definition

Atomic and Nuclear Radii

Physics 1C. Lecture 29A. "Nuclear powered vacuum cleaners will probably be a reality within 10 years. " --Alex Lewyt, 1955

ABC Math Student Copy

Nuclear Chemistry. Lecture 10

MODERN PHYSICS. A. s c B. dss C. u

Nuclides with excess neutrons need to convert a neutron to a proton to move closer to the line of stability.

Radioactivity. The Nobel Prize in Physics 1903 for their work on radioactivity. Henri Becquerel Pierre Curie Marie Curie

7.2 RADIOACTIVE DECAY HW/Study Packet

Complete the table by ticking one box in each row to identify the appropriate isotope. The first row has been completed for you.

The United States Nuclear Regulatory Commission and Duke University Present: Regulatory and Radiation Protection Issues in Radionuclide Therapy

Using the same notation, give the isotope of carbon that has two fewer neutrons.

Objectives: Atomic Structure: The Basics

Fundamental Stellar Parameters. Radiative Transfer. Stellar Atmospheres. Equations of Stellar Structure

Composite Nucleus (Activated Complex)

Every atom has a nucleus which contains protons and neutrons (both these particles are known nucleons). Orbiting the nucleus, are electrons.

CHAPTER 12 The Atomic Nucleus

Chapter 32 Lecture Notes

The wavefunction ψ for an electron confined to move within a box of linear size L = m, is a standing wave as shown.

Radioactive Decay and Radiometric Dating

Visit for more fantastic resources. AQA. A Level. A Level Physics. Particles (Answers) Name: Total Marks: /30

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

Section 10: Natural Transmutation Writing Equations for Decay

Basic Nuclear Theory. Lecture 1 The Atom and Nuclear Stability

We will consider the physics of each of these processes. Physics 273 Radioactivity

Lecture 02. The Standard Model of Particle Physics. Part I The Particles

Physics 30: Chapter 8 Exam Nuclear

Nicholas J. Giordano. Chapter 30. Nuclear Physics. Marilyn Akins, PhD Broome Community College

9 Nuclear decay Answers to exam practice questions

Physics 142 Modern Physics 2 Page 1. Nuclear Physics

Nuclear Binding, Radioactivity

From Last Time. Stronger than coulomb force, But much shorter range than coulomb force.

Physics of Radioactive Decay. Purpose. Return to our patient

T7-1 [255 marks] The graph shows the relationship between binding energy per nucleon and nucleon number. In which region are nuclei most stable?

(3) (1) Complete the equation below to represent the emission of an α particle by a nucleus. Th + α

[1] (c) Some fruits, such as bananas, are naturally radioactive because they contain the unstable isotope of potassium-40 ( K.

Transcription:

Chem 481 Lecture Material 1/30/09 Nature of Radioactive Decay The Standard Model in physics postulates that all particles in nature are composed of quarks and leptons and that they interact by exchange force carrier (virtual) particles (see tables below). Protons and neutrons are composites consisting of three quarks, uud for protons and udd for neutrons. The quarks in a proton or neutron are held together by the fundamental strong force involving the exchange of gluons as described by quantum chromodynamics (QCD). Protons and neutrons interact via the residual strong force (nuclear force) that involves quarks in one nucleon interacting with quarks in another nucleon. The nuclear force can also be described in terms of the exchange of π mesons between nucleons. This interaction is stronger than the electromagnetic force and is responsible for keeping a collection of protons in the nucleus intact. An excellent summary of the fundamentals of forces and particles can be found at: http://www.particleadventure.org/frameless/decay_intro.html

page 2 Conservation Laws In addition to the conservation of energy, charge, momentum, etc., other conservation laws govern particle interactions and decay processes. Two important conservation laws are the conservation of baryon number and the conservation of lepton number. For nuclear decay processes and nuclear reactions, the conservation of charge and baryon number are manifested in the balancing of subscripts and superscripts in the equation for the reaction.

page 3 Alpha Decay Alpha (α) decay involves the emission of a packet of 2 protons and 2 neutrons from a nucleus. The α particle has a +2 charge and usually represented in α decay reactions as 4 2He (the ultimate fate of the charged α particle is to pick up 2 electrons and become an atom of 4 He). The emitted α particles are either monoenergetic or consist of a few monoenergetic groups. general α decay equation: A ZX 6 A-4 Z- 2X + 4 2He + Q example: 226 8 8Ra 6 222 8 6Rn + 4 2He + Q For alpha decay, For the α decay of 22 6 88Ra, The Chart of the Nuclides lists for 226 Ra: α 4.78442, 4.602... γ 186.2 This means that alpha particles of several energies are emitted, with 4.78 MeV being the dominant one, along with a gamma ray of 186.2 kev. The gamma emission results from the 222 Rn being formed in an excited state which then de-excites by photon emission. Detailed information about decay schemes is found in the Table of Isotopes. The information found for 226 Ra is shown below. Note that the decay scheme is a plot of relative energy vs Z.

page 4 In order to conserve momentum when the alpha particle is emitted it, the much heavier product nucleus recoils with a small amount of energy (E r ) analogous to the recoil felt when firing a gun. This means that the kinetic energy of the alpha particle (E α ) is only a portion of the decay energy. Thus, one can write: Q = E r + E α = ½m r v r 2 + ½m α v α 2 and m r v r = m α v α (assuming a stationary parent) For 226 Ra, The recoil energy of the daughter is sufficient to break chemical bonds if the parent is bound to other atoms. Although nuclei with A$140-150 are unstable with respect to alpha decay, this decay mode is usually observed only if A$210. The range of α particles energies is from about 2-10 MeV (usually 5-7 MeV), yet α decay half lives range from ~10-7 s to >10 19 y. There is a strong inverse relationship between E α and half life. Since E α is much less than the Coulomb barrier of the nucleus, the particle should be trapped inside the nucleus. George Gamow (1928), and independently, R.W. Gurney and E.U. Condon, proposed that alpha emission occurs via quantum mechanical tunneling (see figure below).

page 5 This led to the relationship know as the Geiger-Nuttall rule which is its modern form is: where 8 is the decay constant (= ln2/t ½ ); Z is the parent atomic number; E is the decay energy; a 1 and a 2 are constants. The energy released in alpha emission is equal to the E B of the α particle (28.3 MeV) minus the energy needed to remove 2 p and 2 n from the nucleus. E B /A decreases with increasing A and around A =150 α emission is exoergic, but measurable decay rates are not observed until A > 210 because the Coulomb barrier increases more slowly with A than does the decay energy. The emission of other charged particles is not common because their E B is not so large compared to that of the most loosely bound nucleons in the nucleus (for example, E B for 2 H is only 2 MeV). Negatron (β - ) Decay In β - decay a neutron is converted to a proton with the subsequent emission of a highenergy electron and an electron antineutrino ( ~ ν e ). general β - decay equation: A A 0 ZX 6 Z+ 1X + - 1e + 0~ 0 ν e + Q example: For β - decay, 56 2 5Mn 6 56 2 0 6Fe + - 1e + 0~ 0 ν e + Q (Note that the mass of e - is taken into account by the daughter electrons.) Alternatively,

page 6 For the β - decay of 5 6 25Mn, Decay information for 56 Mn from the Table of Isotopes is given below.

page 7 Notice that 56 Mn does not decay to the ground state of 56 Fe. The closest the decay gets is to the 847-keV excited state which rapidly de-excites with emission of a gamma ray of this energy. Thus, one would expect E β- = 3.696 MeV - 0.847 MeV = 2.849 MeV. Surprisingly, a continuous range of β - energies are observed as illustrated in the beta spectrum for 32 P below. To account for this and to allow for conservation of spin, Wolfgang Pauli proposed in 1930 that another particle with spin ½ and no charge was emitted during the decay process. It was not until 1956 that evidence for the existence of neutrinos and antineutrinos was obtained by Reines and Cowan. In the Standard Model the decay of the neutron is associated with a quark transformation in which one of the down quarks in a neutron is converted to an up quark by the weak interaction. Since the down quark has a charge of -1/3 and and the up quark has a charge of 2/3, this process is mediated by a virtual W- particle, which carries away a (-1) charge (thus conserving charge). The new up quark rebounds away from the emitted W-. The neutron has now become a proton. An electron and an electron antineutrino emerge from the virtual W- boson and are emitted from the nucleus. This process is diagrammed below.

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