The Charged Liquid Drop Model Binding Energy and Fission

Similar documents
PHGN 422: Nuclear Physics Lecture 5: The Liquid Drop Model of the Nucleus

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

The nucleus and its structure

Describe the structure of the nucleus Calculate nuclear binding energies Identify factors affecting nuclear stability

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

Mirror Nuclei: Two nuclei with odd A in which the number of protons in one nucleus is equal to the number of neutrons in the other and vice versa.

Lecture 4: Nuclear Energy Generation

Chapter 44. Nuclear Structure

Lecture 2. The Semi Empirical Mass Formula SEMF. 2.0 Overview

13. Basic Nuclear Properties

The liquid drop model

Potential energy, from Coulomb's law. Potential is spherically symmetric. Therefore, solutions must have form

8 Nuclei. introduc)on to Astrophysics, C. Bertulani, Texas A&M-Commerce 1

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

Properties of Nuclei deduced from the Nuclear Mass

Introduction to Modern Physics Problems from previous Exams 3

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

What did you learn in the last lecture?

Lecture 3. Solving the Non-Relativistic Schroedinger Equation for a spherically symmetric potential

Chapter 28. Atomic Physics

Lecture 4. Magic Numbers

Introductory Nuclear Physics. Glatzmaier and Krumholz 7 Prialnik 4 Pols 6 Clayton 4.1, 4.4

RFSS: Lecture 2 Nuclear Properties

Basic Nuclear Theory. Lecture 1 The Atom and Nuclear Stability

Lecture 19: Building Atoms and Molecules

LECTURE 25 NUCLEAR STRUCTURE AND STABILITY. Instructor: Kazumi Tolich

Quantum Numbers. principal quantum number: n. angular momentum quantum number: l (azimuthal) magnetic quantum number: m l

Chapter 9: Multi- Electron Atoms Ground States and X- ray Excitation

c E If photon Mass particle 8-1

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

UNIT 15: NUCLEUS SF027 1

3. Introductory Nuclear Physics 1; The Liquid Drop Model

1 Introduction. 2 The hadronic many body problem

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

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

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

Lecture 19: Building Atoms and Molecules

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

Chapters 31 Atomic Physics

Introduction to Nuclear Science

Nuclear vibrations and rotations

Physics 107: Ideas of Modern Physics

Physics 107: Ideas of Modern Physics

Physics 107 Final Exam May 6, Your Name: 1. Questions

Physics 228 Today: April 22, 2012 Ch. 43 Nuclear Physics. Website: Sakai 01:750:228 or

Nuclear Physics: Models of the Nucleus and Radioactivity ( ) SteveSekula, 8 April 2010 (created 7 April 2010)

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

Electron Configuration

Atomic Structure and Atomic Spectra

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

PHGN 422: Nuclear Physics Lecture 3: Nuclear Radii, Masses, and Binding Energies

PHL424: Nuclear Shell Model. Indian Institute of Technology Ropar

INTRODUCTION. The present work is mainly concerned with the comprehensive analysis of nuclear binding energies and the

Electrons/bonding and quantum numbers

Dalton s Postulates about atoms are inconsistent with later observations :

1. Nuclear Size. A typical atom radius is a few!10 "10 m (Angstroms). The nuclear radius is a few!10 "15 m (Fermi).

14. Structure of Nuclei

Quantum mechanics of many-fermion systems

Atomic and nuclear physics

Properties of Nuclei

Nuclear Physics and Astrophysics

Atoms, Molecules and Solids (selected topics)

The structure of atoms.

Chapter 5. Par+cle Physics

Atomic Quantum number summary. From last time. Na Optical spectrum. Another possibility: Stimulated emission. How do atomic transitions occur?

INSTRUCTIONS PART I : SPRING 2006 PHYSICS DEPARTMENT EXAM

Part II Particle and Nuclear Physics Examples Sheet 4

ECE440 Nanoelectronics. Lecture 07 Atomic Orbitals

A

Lesson 5 The Shell Model

PHY492: Nuclear & Particle Physics. Lecture 6 Models of the Nucleus Liquid Drop, Fermi Gas, Shell

Nuclear Spin and Stability. PHY 3101 D. Acosta

Nuclei with combinations of these three numbers are called nuclides and are written A X or A

Quantum Theory of Many-Particle Systems, Phys. 540

How we describe bonding is affected strongly by how we describe where/how electrons are held by atoms in molecules.

CHAPTER 12 The Atomic Nucleus

CHEM3023: Spins, Atoms and Molecules

DO PHYSICS ONLINE STRUCTURE OF THE ATOM FROM IDEAS TO IMPLEMENTATION ATOMS TO TRANSISTORS STRUCTURE OF ATOMS AND SOLIDS

Nuclear Physics Fundamental and Application Prof. H. C. Verma Department of Physics Indian Institute of Technology, Kanpur

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

The Proper)es of Nuclei. Nucleons

Introduction to Nuclear Science

Nuclear Binding Energy

Nuclear models: The liquid drop model Fermi-Gas Model

Nuclear Physics and Astrophysics

Chemistry 2000 Lecture 1: Introduction to the molecular orbital theory

Krane Enge Cohen Willaims NUCLEAR PROPERTIES 1 Binding energy and stability Semi-empirical mass formula Ch 4

Physics 1C Lecture 29B

Final Exam Tuesday, May 8, 2012 Starting at 8:30 a.m., Hoyt Hall Duration: 2h 30m

II) ACTIVITY: Discovering the periodic trend for atomic radius within the groups of elements.

(b) The wavelength of the radiation that corresponds to this energy is 6

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

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

7/19/2009. Source: Corbis. Mendeleev's early periodic table, published in 1872

Chancellor Phyllis Wise invites you to a birthday party!

Lecture 3. lecture slides are at:

Lecture 3. lecture slides are at:

Earth Solid Earth Rocks Minerals Atoms. How to make a mineral from the start of atoms?

Chapter VIII: Nuclear fission

Materials Science. Atomic Structures and Bonding

Transcription:

The Charged Liquid Drop Model Binding Energy and Fission 103 This is a simple model for the binding energy of a nucleus This model is also important to understand fission and how energy is obtained from fission. 104 1

In the case of a large nucleus a fair number of nucleons are assembled and we know that they attract each other. [As we have seen, the binding energy per nucleon is (very approximately) a constant ~8 MeV.] The volume effect If nucleons attract each other then if a nucleon is surrounded by other nucleons, its energy will be lower than if it is isolated. Therefore the binding energy is proportional to the number of particles in the nucleus (i.e. the volume) so E b! C 1 A The mass number Some constant In other words, if the binding energy per nucleon is a constant, then the total binding energy will be directly proportional to the total number of nucleons. 10 This is reduced because not all of the nucleons are surrounded by other nucleons (i.e. those on the surface). The surface effect The binding energy will therefore be decreased in proportion to the area of the surface. E b! "C 2 A 2 3 The volume is proportional to A so the area of the surface is proportional to A 2 3 Surface Some constant The binding energy is reduced by this effect The nucleons at the surface are not surrounded so their energy is higher 106 2

The (Charged) Liquid Drop Model Taking into account volume and surface effects gives the following expression: E b! C 1 A " C 2 A 2 3 According to this formula, the binding energy per nucleon should increase monotonically as the nucleus gets larger and larger, while we have seen that it goes through a maximum when A is around 6. Something else must be included. What is it? Well we know that nuclei contain protons and we haven t taken the repulsion between these protons into account. 107 The (Charged) Liquid Drop Model So the binding energy is also reduced by Coulomb repulsion between the protons. Coulomb repulsion The nucleus contains Z protons. These are all positively charged and therefore repel each other. If two charged particles are at a distance, r, then their potential energy is. k e q 1 q 2 r The total Coulomb energy of the nucleus is therefore proportional to the number of pairs of charged particles, i.e. Z(Z-1). It is also inversely proportional to the radius of the nucleus. Z(Z!1) Thus the binding energy is reduced by an amount:!c 3, because of the Coulomb repulsion between the protons. 108 3

The (Charged) Liquid Drop Model The binding energy is also reduced by Coulomb repulsion Coulomb repulsion continued We have just waved our hands around and seen that it is reasonable that the Coulomb repulsion reduces the binding energy by an amount:!c 3 Z(Z!1) We can however derive this. Let s do it. 109 The (Charged) Liquid Drop Model Calculation of the Coulomb energy term from first principles. If we consider the electrostatic self-energy of a nucleus we can calculate the Coulomb repulsion term in the liquid drop model.!c 3 Z(Z!1) Consider a nucleus containing Z protons. The radius of the nucleus is. Take a spherical shell at radius r from the centre and of thickness dr. r dr The charge in this shell is 4!r 2 dr" This charge is repelled by the charge within the sphere, i.e. : 4 3!r3 " Charge density! = Ze V C " m-3 110 4

Calculation of the Coulomb energy term from first principles. r dr The nucleus is made up of a whole lot of such spherical shells. The potential energy of the charge in the nucleus can be found by seeing what the potential energy of a typical shell at radius r, and then summing over all the shells (i.e. forming the integral). 111 Calculation of the Coulomb energy term from first principles (continued) r The potential energy of a particular shell at a radius r is just: k e x the charge in the shell (of radius r) x charge inside r x 1/r dr de C 4!r 2 dr" # 4 3!r3 " # 1 r 4!" # 4 3!" # r 4 dr The total potential energy of the charge in the nucleus is then the integral of this over all radii from 0 to. E C 4!" # 4 3!" # $ 4!" # 4!" # 3 0 r 4 dr 112

Calculation of the Coulomb energy term from first principles (continued) Substituting the value! = Ze V C " m-3 for the charge density, r, gives: And then setting the volume, yields: V = 4 3!3 " E C 4! Ze % $ ' ( 4 # V & 3! " Ze % $ ' ( # V & (4!)2 Z 2 e 2 ( 1 ( 4 3! 3 ) 2 3 ( = 3k e Z 2 e 2 So that: E C = 3k e Z 2 e 2 We have calculated directly, from first principles, the reduction of the binding energy that is the result of Coulomb repulsion. 113 Binding energy per nucleon, (MeV) Therefore, taking into account volume, surface and Coulomb repulsion effects gives the following expression: Z 2 E b! C 1 A " C 2 A 2 3 " C 3 9 8 7 6 4 3 2 1 0 How does this fit the experimental data? 0 0 100 10 200 20 Mass number, A This shows the above formula in a fit to the experimental binding energy data (shown previously). In this fit just one free parameter, C 1 = C 2 = 14.7 MeV was used with C 3 = 0.6 MeV.. The fitted curve is pretty good overall, but, for example, it does not reproduce the variations of the light nuclei at all - and the region of maximum binding energy is not correct. 114 6

As we have just seen: E b = C 1 A! C 2 A 2 3! C 3 Z 2 Gives a reasonable if rough fit to the data. But, something is very wrong. What is wrong? Well, why do nuclei contain protons at all? So far, all that the protons do is to reduce the binding energy. In the above model, (so far) a nucleus with Z = 0, i.e. with no protons, only containing neutrons, would actually be very much more stable. 11 Once again, why do nuclei contain protons at all? In order to explain this we need quantum mechanics. Specifically, we need the Pauli exclusion principle. h Nucleons have an intrinsic angular momentum (spin) of. Such 2 particles are fermions and only two fermions of the same type (i.e. two neutrons or two protons) can occupy any energy level, one with spin up and one with spin down. That is the Pauli exclusion principle. The nucleus is a quantum mechanical system and it contains discrete states or energy levels Energy levels (states) Potential well 116 7

The asymmetry energy A schematic, energy level diagram of 3 He protons neutron A nucleus containing two neutrons and one proton in the lowest energy level An additional proton must go into the next energy level An additional neutron can go into the same energy level So, if you add another proton (to make 4 Li), you have a higher energy than if you add another neutron (to make 4 He). 117 Exercise 2 1. Derive the Coulomb self-energy term for a nucleus from first principles. (Make sure you understand it thoroughly.) 118 8

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