Do Now: Label the parts of a wave:

Slides:

Advertisements

Similar presentations

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

Advertisements

Wavelength Visible light wavelength Ultraviolet radiation Amplitude Node Chapter 6: Electromagnetic Radiation.

Wavelength, Frequency, and Energy Practice Problems

The Electromagnetic Spectrum Rainbows plus a whole lot more.

Wavelength Visible light wavelength Ultraviolet radiation Amplitude Node Chapter 6: Electromagnetic Radiation.

Radiant Energy .

Structure of Atoms Rutherford's model of the atom was a great advance, however, it does not give an satisfactory treatment of the electrons. To improve.

wavelength Visible light wavelength Ultraviolet radiation Amplitude Node Chapter 6: Electromagnetic Radiation.

Lecture 15: Electromagnetic Radiation

Lecture 16: Electromanetic Radiation Reading: Zumdahl 12.1, 12.2 Outline –The nature of electromagnetic radiation. –Light as energy. –The workfunction.

EXAM #2 THIS FRIDAY, 10/16 BRING PENCIL, CALCULATOR, AND SHEET OF NOTES (PUT YOUR A00 NUMBER ON IT) CHAPTER 4 OWL ASSIGNMENTS (& FIRST CHAPTER 6 ASSIGNMENT)

Lecture 2010/19/05. wavelength Amplitude Node Electromagnetic Radiation (Light as waves) Moving Waves.

Wave Nature of Light and Quantum Theory

Electron Configurations & the Periodic Table Chapter 7.

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

Section 4.6—Light. Light is Electromagnetic Radiation Electromagnetic energy is energy that has electric and magnetic fields There are many types of Electromagnetic.

Electromagnetic Spectra Review Game. When do electrons emit light? Moving from higher to lower energy levels.

12.6 Light and Atomic Spectra

Wavelength Visible light wavelength Ultraviolet radiation Amplitude Node Chapter 6: Electromagnetic Radiation.

Light and Energy Chemistry I. Classical description of light Light is an electromagnetic wave. Light consists of elementary particles called photons.

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

I. Waves & Particles (p ) Ch. 5 - Electrons in Atoms yC. JOHANNESSON.

The Electromagnetic Spectrum A continuous range of oscillating electric and magnetic waves. The energy in an electromagnetic wave increases as the frequency.

SPECTROSCOPIC CONCEPTS BY Dr.JAGADEESH. INTRODUCTION SPECTROSCOPY: Study of interaction of matter with electromagnetic radiationelectromagnetic radiation.

The Bohr Model for Nitrogen 1. Bohr Model of H Atoms 2.

Light and the Atom. Light Much of what we know about the atom has been learned through experiments with light; thus, you need to know some fundamental.

Electromagnetic radiation – transmission of energy through space in the form of oscillating waves wavelength, – distance between identical points on successive.

ELECTROMAGNETIC RADIATION subatomic particles (electron, photon, etc) have both PARTICLE and WAVE properties Light is electromagnetic radiation - crossed.

Electromagnetic Spectrum Basics Pg

C. Johannesson I. Waves & Particles (p ) Ch. 5 - Electrons in Atoms.

A. Waves  Wavelength ( ) - length of one complete wave  Frequency ( ) - # of waves that pass a point during a certain time period hertz (Hz) = 1/s 

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

The Electromagnetic Spectrum

The Nature of Light – Atomic Spectroscopy and the Bohr Model

CHAPTER 3: Light.

Electromagnetic Energy

The Electromagnetic Spectrum Part 1

Electromagnetic Radiation

Properties of Light Electromagnetic waves are transverse waves (particles vibrate perpendicular to wave direction) that consist of oscillating electric.

Electromagnetic Radiation

4.5 NOTES LIGHT and ENERGY.

The Characteristics of LIGHT

Chemistry 141 Wednesday, October 25, 2017 Lecture 21

Atomic Theory Notes.

Chapter 6: Electromagnetic Radiation

The Study of Light Light is a form of ENERGY.

Chapter 6: Electromagnetic Radiation

Chemistry 141 Friday, October 27, 2017 Lecture 22 Light and Matter

SCH4C Matter & Qualitative Analysis

Electromagnetic Radiation

25.1 The Electromagnetic Spectrum

25.1 The Electromagnetic Spectrum

Goal 4 – The Electromagnetic Spectrum

Chapter 5 Electrons In Atoms 5.3 Atomic Emission Spectra

Electromagnetic Spectrum

Sections 6.1 – 6.3 Electromagnetic Radiation and its Interaction with Atoms Bill Vining SUNY College at Oneonta.

What we measure: Mass Temperature Electromagnetic Radiation

Section 5.1 Light and Quantized Energy

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

Energy Unit Energy of an Electron.

Light and Energy Electromagnetic Radiation is a form of energy that is created through the interaction of electrical and magnetic fields. It displays wave-like.

Atomic Theory Notes.

5.2 Properties of Light Our goals for learning What is light?

Electrons and Light!.

Quantum Physics – Photons Mr Nesbo

Chemistry Unit 3 Chapter 4 and 5 – Atomic Structure

Chapter 9 Lesson 1 Quiz review

Chapter 6: Electromagnetic Radiation

Energy Unit Energy of an Electron.

Presentation transcript:

Do Now: Label the parts of a wave: Why do waves with long wavelengths have low frequencies? Would gamma rays (very high frequencies) have very little energy or lots of energy? What color of visible light (ROYGBIV) has waves with the highest frequencies? Longest wavelengths? Least energy?

Review equations c= λ ν E = h ν E = hc / λ *h = Plack’s constant = 6.626 x 10-34 J*s c=speed of light = 3.00 x 108 m\sec

Objectives: The interaction of electromagnetic waves or light with matter is a powerful means to probe the structure of atoms and molecules.

If the entire electromagnetic spectrum were stretched out to the length of the United States, the piece that would be visible to human eyes would be the size of a dime.

Electromagnetic Radiation: What is it ??? Electromagnetic Radiation: All forms of EM radiation can be described in terms of an oscillating electrical and magnetic field. (waves!) Practice: Microwaves in the US operate at a frequency of 2.45 GHz. What is the wavelength of this radiation?

Energy

Quantization and Planck’s Equation: Planck found a relationship between energy and the frequency of electromagnetic radiation. His equation … E = h v It is observed that matter only emits certain energies! Quantization: only certain energies are allowed

Quantization and Planck’s Equation: Planck found a relationship between energy and the frequency of electromagnetic radiation. His equation … Quantization: only certain energies are allowed These quantized, packets of energy, can also be thought of as VERY tiny particles called photons. (this revises Planck’s equation)

Quantization and Planck’s Equation: Practice: A CD player emits a red light with a wavelength of 685 nm. How much energy does 1 photon of this light have? For 1 mole of photons?

In summary: EM radiation is a broad energy spectrum whose wave-like properties can be described by the equation _____ and whose particle-like energy can be described by the equation _____. Objectives: The interaction of electromagnetic waves or light with matter is a powerful means to probe the structure of atoms and molecules.

Try It: Complete #’s 2, 4, 6, 8 and 9

Try It: Complete #’s 2, 4, 6, 8 and 9