Nuclear Physics and Astrophysics

Similar documents
The Standard Model of Particle Physics - I

Quantum mechanics of many-fermion systems

2007 Section A of examination problems on Nuclei and Particles

Lecture 4: Nuclear Energy Generation

CHAPTER 7 TEST REVIEW

Nuclear Physics and Astrophysics

Applied Nuclear Physics (Fall 2006) Lecture 8 (10/4/06) Neutron-Proton Scattering

Nuclear Physics 3 8 O+ B. always take place and the proton will be emitted with kinetic energy.

Lecture 14 Krane Enge Cohen Williams Nuclear Reactions Ch 11 Ch 13 Ch /2 7.5 Reaction dynamics /4 Reaction cross sections 11.

Properties of Nuclei deduced from the Nuclear Mass

PHY-105: Introduction to Particle and Nuclear Physics

Compound and heavy-ion reactions

Activity 12: Energy from Nuclear Reactions

DISCRETE SYMMETRIES IN NUCLEAR AND PARTICLE PHYSICS. Parity PHYS NUCLEAR AND PARTICLE PHYSICS

NERS 311 Current Old notes notes Chapter Chapter 1: Introduction to the course 1 - Chapter 1.1: About the course 2 - Chapter 1.

13. Basic Nuclear Properties

Quantum Mechanics. Exam 3. Photon(or electron) interference? Photoelectric effect summary. Using Quantum Mechanics. Wavelengths of massive objects

SECTION A: NUCLEAR AND PARTICLE PHENOMENOLOGY

Intro to Nuclear and Particle Physics (5110)

Nuclear Shell Model. Experimental evidences for the existence of magic numbers;

Nuclear Physics and Astrophysics

UGC ACADEMY LEADING INSTITUE FOR CSIR-JRF/NET, GATE & JAM PHYSICAL SCIENCE TEST SERIES # 4. Atomic, Solid State & Nuclear + Particle

Lecture 01. Introduction to Elementary Particle Physics

c E If photon Mass particle 8-1

Nuclear and Radiation Physics

Energy Level Energy Level Diagrams for Diagrams for Simple Hydrogen Model

Chem 481 Lecture Material 1/30/09


RFSS: Lecture 8 Nuclear Force, Structure and Models Part 1 Readings: Nuclear Force Nuclear and Radiochemistry:

Reminder about invariant mass:

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

Physics 142 Modern Physics 2 Page 1. Nuclear Physics

MIDSUMMER EXAMINATIONS 2001 PHYSICS, PHYSICS WITH ASTROPHYSICS PHYSICS WITH SPACE SCIENCE & TECHNOLOGY PHYSICS WITH MEDICAL PHYSICS

Question 1 (a) is the volume term. It reflects the nearest neighbor interactions. The binding energy is constant within it s value, so.

Contents. Preface to the First Edition Preface to the Second Edition

The Charged Liquid Drop Model Binding Energy and Fission

Radioactivity, Radiation and the Structure of the atom

Atoms, nuclei, particles

PHY492: Nuclear & Particle Physics. Lecture 3 Homework 1 Nuclear Phenomenology

Elementary Particle Physics Glossary. Course organiser: Dr Marcella Bona February 9, 2016

FYS 3510 Subatomic physics with applications in astrophysics. Nuclear and Particle Physics: An Introduction

Lecture 4: Nuclear Energy Generation

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

Introduction to Modern Physics Problems from previous Exams 3

Electron-Positron Annihilation

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

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

Nuclear Reactions and Astrophysics: a (Mostly) Qualitative Introduction

PHYS 5012 Radiation Physics and Dosimetry

Introduction to Nuclear Physics and Nuclear Decay

Nuclear Physics and Astrophysics

Hour Exam 3 Review. Quantum Mechanics. Photoelectric effect summary. Photoelectric effect question. Compton scattering. Compton scattering question

Nuclear Physics and Astrophysics

Chapter VI: Beta decay

Chapter Three (Nuclear Radiation)

SECTION A Quantum Physics and Atom Models

Nuclear and Particle Physics

PHY492: Nuclear & Particle Physics. Lecture 4 Nature of the nuclear force. Reminder: Investigate

The IC electrons are mono-energetic. Their kinetic energy is equal to the energy of the transition minus the binding energy of the electron.

221B Lecture Notes Many-Body Problems I

The Postulates of Quantum Mechanics Common operators in QM: Potential Energy. Often depends on position operator: Kinetic Energy 1-D case: 3-D case

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

Liquid Drop Model From the definition of Binding Energy we can write the mass of a nucleus X Z

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

Gian Gopal Particle Attributes Quantum Numbers 1

PHYSICS CET-2014 MODEL QUESTIONS AND ANSWERS NUCLEAR PHYSICS

14. Structure of Nuclei

[2] State in what form the energy is released in such a reaction.... [1]

Quantum Numbers. Elementary Particles Properties. F. Di Lodovico c 1 EPP, SPA6306. Queen Mary University of London. Quantum Numbers. F.

Fermi gas model. Introduction to Nuclear Science. Simon Fraser University Spring NUCS 342 February 2, 2011

Radioactivity, Radiation and the Structure of the atom

Nicholas I Chott PHYS 730 Fall 2011

Introduction to Nuclei I (The discovery)

PHY492: Nuclear & Particle Physics. Lecture 8 Fusion Nuclear Radiation: β decay

Chapter S4: Building Blocks of the Universe

Allowed beta decay May 18, 2017

O WILEY- MODERN NUCLEAR CHEMISTRY. WALTER D. LOVELAND Oregon State University. DAVID J. MORRISSEY Michigan State University

Part II Particle and Nuclear Physics Examples Sheet 4

Nuclear Force. Spin dependent difference in neutron scattering. Compare n-p to n-n and p-p Charge independence of nuclear force.

u d Fig. 6.1 (i) Identify the anti-proton from the table of particles shown in Fig [1]

Problem Set # 1 SOLUTIONS

Physics 107: Ideas of Modern Physics

Physics 107: Ideas of Modern Physics

Thursday, April 23, 15. Nuclear Physics

Physics 1C Lecture 29B

FACULTY OF SCIENCE. High Energy Physics. WINTHROP PROFESSOR IAN MCARTHUR and ADJUNCT/PROFESSOR JACKIE DAVIDSON

1. What does this poster contain?

Introduction to Nuclear Science

Nuclear and Particle Physics 3: Particle Physics. Lecture 1: Introduction to Particle Physics February 5th 2007

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

Physics 100 PIXE F06

Lecture 8. CPT theorem and CP violation

Examination in Nuclear and Particle Physics

Neutron Interactions Part I. Rebecca M. Howell, Ph.D. Radiation Physics Y2.5321

Chemistry 1000 Lecture 3: Nuclear stability. Marc R. Roussel

fiziks Institute for NET/JRF, GATE, IIT-JAM, M.Sc. Entrance, JEST, TIFR and GRE in Physics

CHAPTER 12 The Atomic Nucleus

Lecture 6-4 momentum transfer and the kinematics of two body scattering

MODERN PHYSICS Frank J. Blatt Professor of Physics, University of Vermont

The Exchange Model. Lecture 2. Quantum Particles Experimental Signatures The Exchange Model Feynman Diagrams. Eram Rizvi

Transcription:

Nuclear Physics and Astrophysics PHY-30 Dr. E. Rizvi Lecture 5 - Quantum Statistics & Kinematics Nuclear Reaction Types Nuclear reactions are often written as: a+x Y+b for accelerated projectile a colliding with (usually stationary) target X producing Y and b reaction products Alternatively this is written as X(a,b)Y Smaller nuclei / particles written inside brackets For example: 35U (n,ɣ)36u Types of Nuclear Reaction Scattering Processes - X and Y are the same (elastic if Y and b are in ground state) Knockout Reactions - if extra particles are removed from the incident nucleus Transfer Reactions - where 1 or nucleons are exchanged between projectile and target

Nuclear Decay Kinematics Energy level diagrams often used to illustrate radiative transitions between states Much used in atomic physics Make use of this in nuclear decay transitions But, decays may occur to different nuclei X(Z,A) Mass of X Example Parent nucleus X decays to daughter Y via emission of α particle Daughter is written horizontally displaced α Vertical height is energy difference in MeV known as the Q value Q Mass of Y + α Excited nuclear states (isomers) have larger mass (i.e. less binding energy) Y(Z-,A-4) Written as * to indicate excited state Q [M (Z, A) M (Z, A 4) M (, 4)] c The available kinetic energy goes to the α-particle and recoil of daughter If Q>0 then α-decay is possible (but may be forbidden for other reasons) 3 Nuclear Decay Kinematics In general Q-value for any reaction can be defined as: Q4 X Mi (Z, A)c i X f 3 Mf (Z, A)c 5 summing over all initial state particles i, and final state particles f Q is net energy released (or required) in the reaction If a particle is left in an excited state e.g. Y*, Q must include mass-energy of this state Q0 [MX M MY ] c Q since E MY c MY c + E Q-value may be positive, negative or zero Q>0 exothermic nuclear mass / binding energy is released as kinetic energy Q<0 endothermic initial kinetic energy is converted into nuclear mass or binding energy 4

Energy-Momentum Conservation Conservation of total relativistic energy-momentum for our basic reaction gives: a+x Y+b MX c + T X + MA c + T A MY c + T Y + MB c + T B where T are kinetic energies Reaction Q value is defined by analogy with radioactive decays: Q (Mi Tf Mf )c Ti 5 Conservation Laws When analysing nuclear reactions we apply conservation laws: Energy-Momentum: Usually used to determine energy of excited states Charge: The total electric charge is conserved in reactions Proton and Neutron Number Applied in low energy processes where quark exchange takes place Angular Momentum Spin of initial particles and orbital angular momentum is conserved and used to deduce spins of final state nucleons Parity Spatial inversion symmetry also valid for the strong nuclear force Time Time reversal symmetry, most physics laws are indep of time running forwards or backwards some of these are not exact, or cannot be applied universally 6

Symmetries Many forces and phenomena in nature exhibit symmetries An object has a symmetry if an operation/transformation leaves it invariant Rotational Symmetry Reflection Symmetry Parity Rectangle reflected about axis is invariant transformation is x -x Squares rotated 90 remain unchanged transformation is θ θ + 90 Mass symmetry Time symmetry m1 m m m1 F G G r r Reflections about the t0 axis are invariant transformation is t -t Newtons Law is symmetric about transformations of m1 and m (Not really a mass symmetry but the associative property of multiplication) 7 Parity L z Parity is simply a reflection about a given axis in space In 3d we reflect object about all three Cartesian axes B x -x anti-clockwise rotation A B A y -y z -z A a B b y L Some quantities do not flip sign: L spin or angular momentum This remains the same after a parity inversion a b x anti-clockwise rotation a b 8

Parity In terms of wave-functions of a state in a parity invariant potential: V (r) V ( r) (r) ( r) then: If V(r) is unchanged then resulting stationary states must be even or odd parity V(r) odd even r ( r) + (r) even ( r) odd V (r) 6 V ( r) ( r) ± (r) then (r) (r) ( r) 9 Quantum Statistics Before continuing, we need to understand some quantum statistical effects for indistinguishable particles Consider electrons in Helium atom at positions r1 and r and in states ψα and ψb Choose combined wave function to be: A (r1 ) B (r ) Interchanging the two electrons we get: BA B (r1 ) A (r ) But, if a measurement could detect the interchange then they are not indistinguishable Therefore this -particle combined wave function is no good! 10

Quantum Statistics For truly indistinguishable particles, probability densities must be invariant to exchange i.e. ψαβ can differ by sign only from ψβα Wave-functions are symmetric if + BA Wave-functions are anti-symmetric if BA Experiments show that particles with integer spin (0,1,...) have symmetric wave-functions For half integer spin particles (1/, 3/, 5/...) wave-functions are anti-symmetric Spin intrinsic angular momentum of a particle measured in units of ħ Instead, for two particle systems take wave function of the form: bosons : integer spin + fermions: half integer spin 1 [ A (r1 ) B (r ) ± B (r1 ) A (r )] 11 Pauli Exclusion Principle A special case exists for identical quantum states A and B Anti-symmetric combined wave function vanishes i.e. probability density 0 everywhere if 1 [ A A (r1 ) B (r ) B then ± B (r1 ) A (r )] 0 This is the Pauli Exclusion Principle: Two identical fermions cannot exist in the same quantum state This determines the filling of atomic electrons in shells Also nucleons in nuclear 'orbitals' Will play a crucial role in describing nucleon behaviour in nuclei 1

Nucleon-Nucleon Scattering Back to the point. In order to understand nuclear forces we perform nucleon-nucleon scattering experiments (just like Rutherford / Hofstadter) Understanding nucleon-nucleon interactions is relevant to all phenomena covered in this course Also essential for applied phenomena e.g. medical treatment & solar fusion Such scattering experiments still performed today at much higher energies by particle physicists e.g. looking at structure within a proton 13 Similar scattering experiments continue as particle physics experiments resolve structure deep within nucleons quarks & gluons LHC resolved scale ~ λ hc/e h ~ 4 x 10-15 ev s c ~ 3 x 108 ms-1 E ~ 1013 ev (10 TeV) λ ~ 10-0 m!!! 14

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