INVASIONS IN PARTICLE PHYSICS Compton Lectures Autumn 2001 Lecture 3 Oct. 20 2001.

Slides:

Advertisements

Similar presentations

Unit 2 Notes – Radioactivity

Advertisements

Chapter 11 Radioactive Elements.

20th Century Discoveries

ATOM Chapter 14. I CAN IDENTIFY THE PROPERTIES OF THE THREE SUBATOMIC PARTICLES OF ATOMS. I CAN USE A MODEL TO REPRESENT THE STRUCTURE OF AN ATOM AND.

Fundamental Forces of the Universe

The Atomic Nucleus and Radioactivity The nucleus is composed of particles called nucleons, which are protons and neutrons. The number of nucleons is called.

A nucleus can be specified By an atomic number and a Mass number.

Nuclear / Subatomic Physics Physics – Chapter 25 (Holt)

The Pion CROP: Roncalli Division Timothy Willett Roy Lehn Dwight Johns.

Modern Physics LECTURE II.

8/5/2002Ulrich Heintz - Quarknet Particle Physics what do we know? Ulrich Heintz Boston University.

Nuclear Force and Particles

Learning Targets I can name the force that holds the atom’s nucleus together I can describe the two reasons why some isotopes are radioactive. I can describe.

Nuclear Physics Physics 12. Protons, Neutrons and Electrons  The atom is composed of three subatomic particles: Particle Charge (in C) Symbol Mass (in.

Nuclear Stability and Radioactivity AP Physics B Montwood High School R. Casao.

Matching the Content to Your Class (I was told there would be no math)

Radioactivity Nuclear Chemistry

Radiation: Particles and Energy.

PHYS 221 Recitation Kevin Ralphs Week 14. Overview Nuclear Physics – Structure of the Nucleus – Nuclear Reactions.

Nuclear Chemistry. Two main forces in nucleus  Strong nuclear force—all nuclear particles attract each other  Electric forces—protons repulse each other.

Nuclear radiation. What do we mean by Radioactivity? Radioactive decay is the process in which an unstable atomic nucleus loses energy by emitting radiation.

Lecture 29 Elementary Particles and Quarks

Why do some isotopes decay and others don’t? Generally, the less energy a nucleus has, the less likely it is to decay Nuclei move in the direction of lower.

Atomic Structure Basic and Beyond. What are the 3 major parts of an atom? Protons Electrons Neutrons.

Standard Model A Brief Description by Shahnoor Habib.

Elementary Particles: Physical Principles Benjamin Schumacher Physics April 2002.

Nuclear Decay Notes Stability Curve Atomic number Z Neutron number N Stable nuclei Z = N Nuclear particles are held.

Modern Physics. Answer Me!!! How much energy does a photon have if the light beam has a wavelength of 720 nm?

S-145 What is the difference between the terms radioactive and radiation?

The nucleus consists of protons and neutrons, collectively called nucleons. The number of protons is the atomic number. Protons plus neutrons is the atomic.

Dr. Bill Pezzaglia Particle Physics Updated: 2010May20 Modern Physics Series 1 ROUGH DRAFT.

Aim: How can we explain the four fundamental forces and the standard model? Do Now: List all the subatomic particles that you can think of.

Particles and how they interact

The Nucleus Nucleons- the particles inside the nucleus: protons & neutrons Total charge of the nucleus: the # of protons (z) times the elementary charge.

Nuclear Radiation 9.2. The Nucleus Protons and neutrons Charge of electrons and protons – x C = e –Proton +e –Electron -e.

Radioactivity Physics 12 Adv. Radioactivity Radioactive decay is the emission of some particle from a nucleus which is accompanied by a change of state.

Topic 7.2 The ABC’s of Radioactivity

Classification of Particles

Nuclear Radiation Half-Life. What is Radiation? Penetrating rays and particles emitted by a radioactive source Result of a nuclear reaction! –Involves.

Nuclear Physics and Radioactivity AP Physics Chapter 30.

A photon with a wavelength of 2

Types of Radioactive Decay Kinetics of Decay Nuclear Transmutations

Atomic Theory CMS Science 4.0. Development of Atomic Models Atom - the smallest particle of an element Our atomic theory has grown as models were tested.

Prepared By: Shakil Raiman.  Atoms are made up of electrons, protons and neutrons.  The diameter of the nucleus is about 10,000 times smaller than the.

Nuclear Physics. Nuclear Structure Nucleus – consists of nucleons (neutrons and protons) Nucleus – consists of nucleons (neutrons and protons) Atomic.

Nuclear Physics Chapter Li lithium name symbol atomic number (# of p + ) average atomic mass electrons in outer energy level.

GROUP 4 Firdiana Sanjaya ( ) Ana Alina ( )

Take out hwk & tables. Compare answers to hwk sets.

What makes up the nucleus? Nucleus is positively charged Different atoms have same electrical properties but different masses Isotopes – same atomic number,

Chapter 14 Section 14.1.

Lecture 7 The Atom and Elements Subatomic Particles Isotopes Radioactivity.

Honors Physics Chapter 25: Subatomic Physics.  Nucleons  Protons and Neutrons that Make Up the Nucleus  Atomic Number (Z)  # of Protons  Atomic Mass.

Nuclear Reactions 1.To investigate the composition of gold foil using alpha particles (i.e. to explain the model of an atom).

Chapter 10 Nuclear Decay. Objectives 〉 What happens when an element undergoes radioactive decay? 〉 How does radiation affect the nucleus of an unstable.

Discovery of the nucleus Rutherford carried out experiments to see what happened when alpha particles (2 neutrons and 2 protons) were fired at metal foil.

II. The Nucleus of the Atom. What makes up the nucleus of an atom? A. Compostion (Nucleons) 1. Protons a. Mass universal mass units b. Indicated.

Unstable Nuclei and Radioactive Decay. Radioactivity (Radioactive decay) The process by which some substances spontaneously emit radiation. Radioactive.

The Atomic Nucleus.

Unit 5.2 Nuclear Structure

Particle Physics and The Standard Model

ELEMENTARY PARTICLES.

Subatomic Particles and Quantum Theory

Do Now An electron in a hydrogen atoms drops from n=5 to n=4 energy level. What is the energy of the photon in eV? What is the frequency of the emitted.

Nuclear Chemistry.

Quarks Remember the family of ordinary matter consists of only 4 particles, (not counting their antiparticles) quark u d lepton (electron) e Lepton (electron.

Chapter 14 Section 14.1.

Outside nucleus in electron cloud

Modern Studies of the Atom

Atomic Structure Basic and Beyond.

Atomic Structure Basic and Beyond.

Presentation transcript:

INVASIONS IN PARTICLE PHYSICS Compton Lectures Autumn 2001 Lecture 3 Oct

2 LECTURE 2 Cosmic Invasion The muon and the pion Previous Lecture

3 Rutherford Scattering 1.Most of the atom is empty space. 2.The positive charge of the atom is concentrated in a tiny nucleus. 3.The tiny nucleus has a huge mass. 4.Rutherford named the Hydrogen nucleus proton

4 THE NEUTRON (n)  Originally it was thought that protons and electrons make up the atomic nucleus, because these were the only known particles and because some unstable nuclei were known to emit electrons.  The Nitrogen nucleus was measured to have spin 1. It has +7 charge, so for the atom to be neutral it would have to have +14(protons)-7(electrons)=+7 charge in the nucleus and 14+7=21 particles (each with spin ½ (up or down)) in the nucleus. There is no way the total spin can be 1.

5  The idea in the 30s was that there existed a neutral object of ½ spin in the nucleus (Rutherford’s idea) and for example the Nitrogen nucleus is (7 protons+7 neutrons)  Chadwick found the neutron (1932)

6  Alpha (  )  beta (  )  gamma (  )

7 ALPHA DECAY

8 BETA DECAY

9 excited nucleus  unexcited (same) nucleus + gamma GAMMA RADIATION

10

11 Gravity too weak Electromagnetism wrong sign

12 The size of the nucleus is m 1ft 215 ft outer electron Pluto Earth sun gold nucleous 3.3 miles 1.6 miles

13 A “short range” ( m) force is needed to hold the nuclear pieces together What makes a force “short range”??

14 BACK TO THE PHOTON: The photon which has zero mass is the messenger of the electromagnetic force. The range of the electromagnetic (EM) force is infinite -The EM force can be attractive or repulsive.

15  The nuclear force that keeps the nuclear pieces together must act at very small distances (the size of the nucleus).  It must be attractive between proton and proton proton and neutron neutron and neutron which is to say independent of the charge

16  A clue for the “short range” of this force: bigger heavier nuclei decay into smaller more stable nuclei.  This force is gluing the closest neighboring nucleons; Too many protons in a nucleus will cause it to break up -- the nuclear stability is described in part by the repulsive electrical forces between the protons and in part by the new short range strong nuclear force between the nucleons.  Why is it not that we can dilute the repulsive effects of the protons’ electric charges by adding arbitrary number of neutrons in the nucleus?

17  Who is the messenger? What is the mass of the messenger?  From the size of the nucleus and the uncertainty principle it was figured that a particle of about 200 MeV (1/5 of the mass of the proton and 400 times the mass of the electron) should be the messenger of this nuclear force.  H. Yukawa in 1934 predicted this particle which he called a meson (meson because it was middle-weight)

18 Anderson had already discovered the positron in a cloud chamber in In 1937 a middle-weight particle was discovered in cloud chamber experiments by two groups of scientists. (Carl D. Anderson and Seth H. Neddermeyer of California Institute of Technology and Jabez C. Street and Edward C. Stevenson of Harvard.) The new particle’s mass was close to Yukawa’s predicted pi- meson (pion,  ) mass so Andreson et al. thought that was it!

19 POSITRON IN CLOUD CHAMBER

20 Ionizing radiation that does not originate from the earth :cosmic rays. In 1905 Victor Hess performed a series of high-altitude balloon experiments and concluded that the origin of this radiation is beyond the Earth’s atmosphere. Cosmic rays were the only source of high energy particles to study until accelerators were developed.

21

22  The alleged pi-meson that Anderson et al. discovered, seemed very reluctant to interact with the atomic nuclei: it penetrated Earth’s atmosphere and reached the cloud chamber at ground level!  For a particle that was expected to be the carrier of the nuclear force that behavior was unacceptable.  WHAT WAS IT? 

23  A particle that had no purpose of existence.  A heavier version of the electron (about 200 times heavier) that decays into and electron in about 2 microseconds.  I.I. Rabi : “Who ordered that?”  The muon is not a meson at all; like the electron is a lepton.  Why this repetition? It is still not obvious today.

24 The pion was discovered by Cecil Powel and Giuseppe Occhialini in 1947 using photographic emulsions at the Pic du Midi, high in the French Pyrrenees.

25 (200 times heavier that the electron) (273 times heavier that the electron) + -

26 DECAY CONCEPTS  For each particle there is a probability  that it will decay in a unit time.  If we have N(0) particles at t=0 we will have N(t)=N(0)exp(-  t) at a later time t.  For a single particle it means that if the particle exists at t=0, it has a probability exp(-GT) to still be there at time t=T.

27  We say that a particle has lifetime  =1/   We say that  is the “width” of the particle.   m=  (From E=mc 2 and  t=h/2   A DECAYING PARTICLE DOES NOT HAVE A DEFINITE MASS BUT A SPREAD OF MASSES GIVEN BY .  There is a force that causes a particle to decay. If the force is weak the particle will live for a long time. If the force is strong it will live for short time.

28

29   nucleons : neutrons (n) and protons (p)  hadrons : all particles affected by the strong nuclear force  baryons : hadrons which are fermions (such as the nucleons)  mesons : hadrons which are bosons (such as the pion)  leptons : all particles not affected by the strong nuclear force (such as the electron and the muon)

30

31

32