Lecture 2: Quantum Mechanics and Relativity

Similar documents
Chapter 10: Wave Properties of Particles

Particles and Waves Particles Waves

λ = h = h p mv λ = h mv FXA 2008 Candidates should be able to :

Chapter 37 Early Quantum Theory and Models of the Atom

The Structure of the Atom Review

Lecture 15 Notes: 07 / 26. The photoelectric effect and the particle nature of light

Dual Nature of Radiation and Matter GLIMPSES 1. Electron. It is an elementary particle having a negative charge of 1.6x C and mass 9.1x kg

The Photoelectric Effect

Chapter 27 Early Quantum Theory and Models of the Atom Discovery and Properties of the electron

Radiation - Electromagnetic Waves (EMR): wave consisting of oscillating electric and magnetic fields that move at the speed of light through space.

WAVES AND PARTICLES. (c)

Theory English (Official)

DEVIL PHYSICS THE BADDEST CLASS ON CAMPUS IB PHYSICS

WAVE PARTICLE DUALITY

Lecture 11 Atomic Structure

PHY293 Lecture #9. df hf

PHYS 3313 Section 001 Lecture #11

DUAL NATURE OF RADIATION AND MATTER

General Physics (PHY 2140)

1. Historical perspective

Nanoelectronics 04. Atsufumi Hirohata Department of Electronics. Quick Review over the Last Lecture ' E = A. ' t gradφ ' ) / ' ) ε ρ

AP Physics Study Guide Modern Physics I. Atomic Physics and Quantum Effects 1. Who is generally credited with the discovery of the electron?

Explain how Planck resolved the ultraviolet catastrophe in blackbody radiation. Calculate energy of quanta using Planck s equation.

Chapter 27 Quantum Physics

Chapter 28: Quantum Physics. Don t Copy This. Quantum Physics 3/16/13

Dual Nature of Radiation and Matter

Dual Nature of Matter

Physics Lecture 6

The Wave Nature of Matter *

Quantum Mysteries. Scott N. Walck. September 2, 2018

We also find the development of famous Schrodinger equation to describe the quantization of energy levels of atoms.

PSI AP Physics How was it determined that cathode rays possessed a negative charge?

QUANTUM MECHANICS Chapter 12

Complementi di Fisica Lectures 10, 11

Lecture 4 Introduction to Quantum Mechanical Way of Thinking.

PHY 571: Quantum Physics

Lecture 6 - Atomic Structure. Chem 103, Section F0F Unit II - Quantum Theory and Atomic Structure Lecture 6. Lecture 6 - Introduction

Early Quantum Theory and Models of the Atom

12 - DUAL NATURE OF RADIATION AND MATTER Page 1

The Death of Classical Physics. The Rise of the Photon

Quantum and Atomic Physics - Multiple Choice

is the minimum stopping potential for which the current between the plates reduces to zero.

Lecture PowerPoints. Chapter 27 Physics: Principles with Applications, 7th edition Giancoli

Planck s Quantum Hypothesis Blackbody Radiation

Module 02: Wave-particle duality, de Broglie waves and the Uncertainty principle

Downloaded from

Chapter 1. From Classical to Quantum Mechanics

Part 3: HANDS-ON ACTIVITIES

Radiation and the Atom

Chapter 38. Photons Light Waves Behaving as Particles

Quantum Physics and Atomic Models Chapter Questions. 1. How was it determined that cathode rays possessed a negative charge?

Learning Objectives and Worksheet I. Chemistry 1B-AL Fall 2016

Chapter 37 Early Quantum Theory and Models of the Atom. Copyright 2009 Pearson Education, Inc.

Early Quantum Theory & Models of the Atom (Ch 27) Discovery of electron. Blackbody Radiation. Blackbody Radiation. J. J. Thomson ( )

12/04/2012. Models of the Atom. Quantum Physics versus Classical Physics The Thirty-Year War ( )

I. Multiple Choice Questions (Type-I)

Title / paragraph example Topic: Quantum Computers. Course essay. Photoelectric effect summary. From Last Time. Photon interference?

object objective lens eyepiece lens

CHAPTER 27 Quantum Physics

Physics 116. Nov 21, Session 31 De Broglie, duality, and uncertainty. R. J. Wilkes

1 The Cathode Rays experiment is associated. with: Millikan A B. Thomson. Townsend. Plank Compton

Complementi di Fisica Lectures 7-9

Quantum Interference and Duality

Chapter 22 Quantum Mechanics & Atomic Structure 22.1 Photon Theory of Light and The Photoelectric Effect Homework # 170

General Physics (PHY 2140) Lecture 15

GSI Helmholtzzentrum für Schwerionenforschung. Indian Institute of Technology Ropar

Unit 1 Week 1. July XX August XX, 2010

Physics data booklet. First assessment 2016

Quantum Mechanics: Discretization of Energy and Wave-Particle Duality

27-1 Planck Solves the Ultraviolet Catastrophe

5.111 Principles of Chemical Science

Chapter 4: The Wave Nature of Matter

Title / paragraph example Topic: Quantum Computers. Course Essay. Photoelectric effect summary. From Last Time. Compton scattering

The University of Hong Kong Department of Physics

Relativity and Charged Particle Motion in Magnetic Fields

PHYS 3313 Section 001 Lecture #12

Exercise 1 Atomic line spectra 1/9

Chapter 27. Quantum Physics

MIDTERM 3 REVIEW SESSION. Dr. Flera Rizatdinova

Lecture Outline Chapter 30. Physics, 4 th Edition James S. Walker. Copyright 2010 Pearson Education, Inc.

( ) # velocity. Wavelengths of massive objects. From Last Time. Wavelength of electron. Wavelength of 1 ev electron. A little complicated ( ) " = h mv

PHY202 Quantum Mechanics. Topic 1. Introduction to Quantum Physics

Semiconductor Physics and Devices

Photoelectric Effect & Bohr Atom

Photoelectric effect

4/14/2015. Models of the Atom. Quantum Physics versus Classical Physics The Thirty-Year War ( ) Classical Model of Atom

Question 11.1: Find the

Chapter 27 Early Quantum Theory and Models of the Atom

Outline Chapter 9 The Atom Photons Photons The Photoelectron Effect Photons Photons

CHAPTER 12 TEST REVIEW

SECTION A Quantum Physics and Atom Models


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

Module 1. An Introduction to Radiation

CHAPTER 3 The Experimental Basis of Quantum

Stellar Astrophysics: The Interaction of Light and Matter

Complementi di Fisica Lectures 3, 4

1 (a) Sketch the electric field surrounding the gold nucleus drawn below. (3)

Rough Schedule. Units often used in Elementary Particle Physics

CHE3935. Lecture 2. Introduction to Quantum Mechanics

Transcription:

Lecture 2: Quantum Mechanics and Relativity Atom Atomic number A Number of protons Z Number of neutrons A-Z Number of electrons Z Charge of electron = charge of proton ~1.6 10-19 C Size of the atom ~10-10 m Size of the nucleus ~10-15 m

Two questions: Why did Rutherford need α particles to discover the atomic nucleus? Why do we need huge accelerators to study particle physics today? Observation of very small objects using visible light opaque screen with small circular aperture point-like light source λ = 0.4 mm (blue light) photographic plate focusing lenses

Aperture diameter: D = 20 µm Focal length: 20 cm Observation of light diffraction, interpreted as evidence that light consists of waves since the end of the 17 th century Angular aperture of the first circle (before focusing): α = 1.22 λ / D y (mm) x (mm) Opaque disk, diam. 10 µm in the center Presence of opaque disk is detectable

Opaque disk of variable diameter diameter =.4 µm diameter =.2 µm diameter =.1 µm no opaque disk The presence of the opaque disk in the center is detectable if its diameter is larger than the wavelength λ of the light The RESOLVING POWER of the observation depends on the wavelength λ Visible light: not enough resolution to see objects smaller than 0.2 0.3 µm

Opaque screen with two circular apertures aperture diameter: 10 µm distance between centers: 15 µm y (mm) Image obtained by shutting one aperture alternatively for 50% of the exposure time x (mm) Image obtained with both apertures open simultaneously y (mm) Light is a wave and can interfere! x (mm)

Photoelectric effect: evidence that light consists of particles glass tube under vacuum Current measurement Observation of a threshold effect as a function of the frequency (wavelength) of the light impinging onto the electrode at negative voltage (cathode): Frequency ν < ν 0 : electric current = zero, independent of luminous flux; Frequency ν > ν 0 : current > 0, proportional to luminous flux INTERPRETATION (A. Einstein): Light consists of particles ( photons )!!!! Photon energy proportional to frequency: E = h ν (Planck constant h = 6.626 10-34 J s) Threshold energy E 0 = hν 0 : the energy needed to extract an electron from an atom (depends on the cathode material) Albert Einstein

Repeat the experiment with two circular apertures using a very weak light source Luminous flux = 1 photon /second (detectable using modern, commercially available photomultiplier tubes) Need very long exposure time aperture diameter: 10 µm distance between centres: 15 µm Question: which aperture will photons choose? Answer: diffraction pattern corresponds to both apertures simultaneously open, independent of luminous flux y (mm) Interference pattern x (mm) Photons have both particle and wave properties simultaneously It is impossible to know which aperture the photon traversed The photon can be described as a coherent superposition of two states

Black body radiation Electromagnetic radiation emitted by hot object. Statistical mechanics lead to ultraviolet catastrophe i.e., amount of energy emitted at short wavelength became infinite. 1900 Planck: One can avoid the UV catastrophe and describe the experimentally measured spectrum IF electromagnetic radiation is Quantized, i.e. comes in little packages of energy E = hν Planck s constant h = 6.626 x 10-27 ergs ν - frequency λ - wavelength ~1/ν

1924: De Broglie s principle Not only light, but also matter particles possess both the properties of waves and particles Relation between wavelength and momentum: λ = h p h: Planck constant p = m v : particle momentum Louis de Broglie Hypothesis soon confirmed by the observation of diffraction pattern in the scattering of electrons from crystals, confirming the wave behaviour of electrons (Davisson and Germer, 1927) Wavelength of the α particles used by Rutherford in the discovery of the atomic nucleus: 34 h 6.626 10 J s 15 λ = 6.7 10 m = 6.7 m 27 7-1 v (6.6 10 kg) (1.5 10 m s ) α α particle mass 0.05 c 10 13 ~ resolving power of Rutherford s experiment cm

Typical tools to study objects of very small dimensions Resolving power Optical microscopes Visible light ~ 10-6 m Electron microscopes Low energy electrons ~ 10-9 m Radioactive sources α-particles ~ 10-14 m Accelerators High energy electrons, protons ~ 10-18 m

Units in Particle Physics Fundamental Units in Physics: mass, length, time (m, kg, s) are not very useful in the world of particle physics. Typical dimensions are: Size of the nucleus ~1 fermi = 10-15 m Mass of the proton m p = 1.672 10-27 kg Energy 1 electron-volt (ev): the energy of a particle with electric charge = e, initially at rest, after acceleration by a difference of electrostatic potential = 1 Volt (e = 1.60 10-19 C) 1 ev = 1.60 10-19 J J=kg m/s 2

Multiples: deca da 10 deci d 10-1 hecto h 10 2 centi c 10-2 kilo k 10 3 mili m 10-3 mega M 10 6 micro µ 10-6 giga G 10 9 nano n 10-9 tera T 10 12 pico p 10-12 peta P 10 15 femto f 10-15 Energy: 1 kev = 10 3 ev ; 1 MeV = 10 6 ev 1 GeV = 10 9 ev; 1 TeV = 10 12 ev Energy of a proton in the LHC (in the year 2007): 7 TeV = 1.12 10-6 J This energy is equal to a body of mass = 1 mg moving at speed = 1.5 m /s (a bee) The conversion constant between MKS and particle physics units is ħc = 197.327 MeV fm My rest mass (weight =80 kg) is: M = 80 kg (3 10 8 m/s) 2 / 1.6 10-19 J/eV = 45 10 14 TeV/c 2

Energy and momentum for relativistic particles Speed of light in vacuum c = 2.99792 x 10 8 m / s (in the absence of magnetic field) Total energy: E = mc 2 = m c 0 2 1 (v/c) 2 m: relativistic mass m 0 : rest mass Expansion in powers of (v/c): (only valid for v/c small) E 1 2 2 = m0 c + m0v +... 2 energy associated with rest mass classical kinetic energy Momentum: p = mv = m 0 v 1 (v/ c) 2 E pc v = c β

E 2 p 2 c 2 = (m 0 c 2 ) 2 (same value in all reference frames) Special case: the photon (v = c in vacuum) relativistic invariant (effective mass) Einstein de Brogile E = h ν λ= h / p E / p = ν λ= c (in vacuum) E 2 p 2 c 2 = 0 photon rest mass m g = 0 Momentum units: ev/c (or MeV/c, GeV/c,...) Mass units: ev/c 2 (or MeV/c 2, GeV/c 2,...) Numerical example: electron with v = 0. 99 c Rest mass: m e = 0.511 MeV/c 2 γ 1 1 (v/ c) 2 = 7.089 (often called Lorentz factor ) Total energy: E = γ m e c 2 = 7.089 x 0.511 = 3.62 MeV Momentum: p = (v / c) (E / c) = 0.99 3.62 = 3.58 MeV/c

Natural System of Units c = 1 E 2 = p 2 + m 2 All quantities in multiples of ev Unit of length 1 fm =1/197.3 MeV Unit of time 1 s = 1/6.58 10-22 MeV

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