THE PHOTOELECTRIC EFFECT. When red light is incident on a clean metal surface: no electrons are released, however long light is shone onto it, however.

Slides:

Advertisements

Similar presentations

Black-body Radiation & the Quantum Hypothesis

Advertisements

RADIO WAVES, MICROWAVES, INFRARED, VISIBLE, ULTRAVIOLET, X-RAYS, GAMMA RAYS HIGH< wavelength LOW.

The Photoelectric Effect Waves as particles? What, are you crazy??

Waves. Characteristics of Waves Frequency Amplitude.

Physics 2 Chapter 27 Sections 1-3.

Blackbody Radiation & Planck’s Hypothesis

Black body radiation BBR is the radiation emitted by a non-reflecting solid body. A perfect black body is one which absorbs all the radiations falling.

Blackbody Radiation & Planck’s Hypothesis

The Rutherford model of the atom was an improvement over previous models, but it was incomplete. J. J. Thomson’s “plum pudding” model, in which electrons.

Electromagnetic Radiation. Definitions Electromagnetic Radiation is energy with wavelike characteristics Moves at a speed of 3.0 x 10 8 m/s.

Caroline Chisholm College

The dual nature of light l wave theory of light explains most phenomena involving light: propagation in straight line reflection refraction superposition,

What are the 3 ways heat can be transferred? Radiation: transfer by electromagnetic waves. Conduction: transfer by molecular collisions. Convection: transfer.

Wave-Particle Duality e/m radiation exhibits diffraction and interference => wave-like particles behave quite differently - follow well defined paths and.

Introduction to Quantum Physics

Black-body Radiation & the Quantum Hypothesis Micro-world Macro-world Lect 13 Max Planck.

Black Body radiation Hot filament glows.

The Photoelectric E ffect By Eleanor Girdziusz. The Photoelectric Effect “The phenomenon that when light shines on a metal surface, electrons are emitted”

Electromagnetic Spectrum. Quantum Mechanics At the conclusion of our time together, you should be able to:  Define the EMS (electromagnetic spectrum.

Particle Nature of Light page 49 of Notebook VISIBLE LIGHT ELECTRONS.

Light and Electrons October 27, 2014.

Particle Properties of Light. Objectives To discuss the particle nature of light.

More About Photoelectricity Quantum Physics Lesson 2.

Energy. Radiant Energy Radiant: think light…. How does light carry energy through space???

Arrangement of Electrons in Atoms The Development of a New Atomic Model.

Thompson’s experiment (discovery of electron) + - V + - Physics at the end of XIX Century and Major Discoveries of XX Century.

Physics 1C Lecture 28A. Blackbody Radiation Any object emits EM radiation (thermal radiation). A blackbody is any body that is a perfect absorber or emitter.

PARTICLE NATURE OF LIGHT. A Black Object Appears black because it absorbs all frequencies of light A black block of iron does this.

Physics 1202: Lecture 30 Today’s Agenda Announcements: Extra creditsExtra credits –Final-like problems –Team in class HW 9 next FridayHW 9 next Friday.

Development of a New Atomic Model Properties of Light.

Modern Atomic Theory Quantum Theory and the Electronic Structure of Atoms Chapter 11.

THE PHOTOELECTRIC EFFECT Objective: Demonstrate the particle nature of light by discussing photoelectric effect. Albert EinsteinTM HUJ,

THE PHOTOELECTRIC EFFECT

PHOTO ELECTRIC EFFECT. When red light is incident on a clean metal surface: no electrons are released, no electrons are released, however long light is.

Light is a Particle Physics 12.

Vocabulary Review New radiation electromagnetic radiation wavelength

Chemistry – Chapter 4. Rutherford’s Atomic Model.

Unit 12: Part 2 Quantum Physics. Overview Quantization: Planck’s Hypothesis Quanta of Light: Photons and the Photoelectric Effect Quantum “Particles”:

Lesson 3 : The Bohr Model. Bohr Model of an Atom  Electrons orbit the nucleus in fixed energy ranges called orbits (energy levels)  An electron can.

Blackbody. Kirchhoff’s Radiation  Radiated electromagnetic energy is the source of radiated thermal energy. Depends on wavelengthDepends on wavelength.

Light is a Particle Physics 12 Adv. Blackbody Radiation A blackbody is a perfect emitter; that is it emits the complete EM spectrum Work done by Gustav.

1© Manhattan Press (H.K.) Ltd Quantum theory.

Section 2.2 and Chapter 7 Electron Configurations and Waves.

4-2 Quantum Theory. Planck’s Theory Max Planck predicted accurately how the spectrum of radiation emitted by an object changes with temperature.

Electromagnetic Radiation. Waves To understand the electronic structure of atoms, one must understand the nature of electromagnetic radiation. The distance.

1© Manhattan Press (H.K.) Ltd Continuous spectra Spectra Sun’s spectrum and Fraunhofer lines.

5.3 Atomic Emission Spectra and the Quantum Mechanical Model 1 > Copyright © Pearson Education, Inc., or its affiliates. All Rights Reserved. Chapter 5.

The Wacky World of Quantum Physics

Plan for Today (AP Physics 2) Questions on HW (due tomorrow) Notes/Lecture on Blackbody Radiation.

Atomic Structure.

Quantized Energy and Photons

ORIGIN OF QUATUM PHYSICS

Topic- Black-Body Radation Laws

Photoelectric effect, photons

Black Body Radiation Mr. Sonaji V. Gayakwad Asst. professor

Atomic Physics & Quantum Effects

PHOTOELECTRIC EFFECT hhhhh 12/4/2018.

THE PHOTOELECTRIC EFFECT

I. Waves & Particles (p ) Ch. 4 - Electrons in Atoms I. Waves & Particles (p )

Waves and particles Ch. 4.

Physics and the Quantum Model

Quantization of light, charge and energy Chapter 2

More About Photoelectricity

Electron Configurations

The Electronic Structure of Atoms

Key Areas covered Photoelectric effect as evidence for the particulate nature of light Photons of sufficient energy can eject electrons from the surface.

Elementary Quantum Mechanics

Photoelectric Effect And Quantum Mechanics.

Quantized Energy and Photons

Presentation transcript:

THE PHOTOELECTRIC EFFECT

When red light is incident on a clean metal surface: no electrons are released, however long light is shone onto it, however intense the light source is. Clean metal surface

When UV light is incident on a clean metal surface: electrons are released instantaneously, however weak the light source. Clean metal surface UV light

Classically this cannot be explained because: If red light is shone onto the metal surface for long enough some electrons should gain sufficient energy to enable them to escape.

Einstein put forward a theory: Light energy is quantized. Light consists of a stream of particles called photons. The energy of each photon ( E ) depends on the frequency ( f ) of the light. on the frequency ( f ) of the light.

Frequency increasing

Red light photons therefore than violet light photons and even less than UV photons Photon energy

GIVES ALL ITS ENERGY TO ONE ELECTRON e ONE PHOTON

eeeeeee surface electrons Clean metal surface A photon of red light gives an electron insufficient energy to enable it to escape from the surface of the metal. Red light photon No electrons are released from the metal surface.

eeeeeee surface electrons Clean metal surface A photon of UV light gives an electron sufficient energy to enable it to escape from the surface of the metal. UV photon Electrons are released instantaneously. Each photon releases an electron This is called photoemission.

BLACKBODY RADIATION

Significance of Black Body The black body concept has a significant role in thermal radiation theory and practice. The black body concept has a significant role in thermal radiation theory and practice. The ideal black body notion is important in studying thermal radiation and electromagnetic radiation transfer in all wavelength bands. The ideal black body notion is important in studying thermal radiation and electromagnetic radiation transfer in all wavelength bands. The black body model is used as a standard with which the absorption of real bodies is compared. The black body model is used as a standard with which the absorption of real bodies is compared.

Definition of a black body A black body is an ideal body which allows the entire incident radiation to pass into itself (without reflecting the energy ) and absorbs within itself (without transmitting the energy). This propety is valid for radiation corresponding to all wavelengths and to all angles of incidence. This renders a black body an ideal absorber of incident radiation.

The UV Catastrophe Pre-1900 theory Theory & experiment disagree wildly

Planck’s solution EM energy cannot be radiated or absorbed in any arbitrary amounts, but only in discrete “quantum” amounts. The energy of a “quantum” depends on frequency as E quantum = h f h = 6.6 x Js “Planck’s constant”

Quanta and the UV catastrophe Low frequency, small quantum, Negligible effects high frequency, large quantum, huge effects Without the quantum With the quantum

Comparison between Classical and Quantum Viewpoints

Conclusion As the temperature increases, the peak wavelength emitted by the black body decreases. As temperature increases, the total energy emitted increases, because the total area under the curve increases. The curve gets infinitely close to the x-axis but never touches it.

Black-body Radiation  peak = 2.9 x m T(Kelvin) Light intensity UVIR

peak vs Temperature peak vs Temperature  peak = 2.9 x m T(Kelvin) T 310 K (body temp) 2.9 x m 310 K =9x10 -6 m 5800 K (Sun’s surface) 2.9 x m 5800 K =0.5x10 -6 m infrared light visible light