Objectives. What are X-rays? X. Julian Moger 1. PAM1014 Introduction to Radiation Physics. Electromagnetic Radiation. Electromagnetic Radiation

Save this PDF as:
 WORD  PNG  TXT  JPG

Size: px
Start display at page:

Download "Objectives. What are X-rays? X. Julian Moger 1. PAM1014 Introduction to Radiation Physics. Electromagnetic Radiation. Electromagnetic Radiation"

Transcription

1 PM1014 Introduction to Radiation Physics Objectives Electromagnetic Waves Properties of Electromagnetic Spectrum Inverse Square Law What are s? X Radio & TV Microwave Visible UV s γ-rays Wavelength in metres Useful Characteristics Penetrate Matter Interact with Matter Cause Certain Materials to Fluoresce Cause Certain Material to Produce Electric Charge single-frequency EM wave exhibits a sinusoidal variation of electric and magnetic fields in space Magnetic variation is perpendicular to electric field λ Electric Field Magnetic Field Electromagnetic Waves Sinusoidal Model mplitude, Electric field Transport energy through space Wavelength Length of one cycle Frequency Hz = cycles per second Energy is stored in the propagating electric and magnetic fields Julian Moger 1

2 Photons Electromagnetic Spectrum photon is the smallest quantity of NY type of electromagnetic radiation Energy disturbances moving through space at the speed of light Frequency Range: Wavelength Range: 10 4 Hz m Regions relevant to medical imaging? c = 3 X 10 8 ms -1 Electromagnetic Spectrum Visual MR Energy (ev) Frequency (Hz) Wavelength (m) 1nm 1μm 1cm 1m 1km Gamma rays s UV Visible Light μ-wave Radio can interact with matter Interacts with particles matter of length scale of the same order as the radiation wavelength Gamma-Ray Gamma-Ray Security stronomy Medical Julian Moger 2

3 Ultraviolet Microscopy stronomy NS s s LNDST satellite Band Name Vis blue Vis green Vis red N Middle Thermal Middle λ (μm) uses Max water penetration Measuring planet vigour Vegetation Biomas & shoreline mapping Moisture content Soil moisture & thermal mapping Mineral mapping Fluorescence Microscopy: Endothelial Cells, strocyte Infrared True color image; the red satellite data (band3) is displayed in red, the green satellite data (band 2) is displayed in green, and the blue satellite data (band 1) is displayed in blue False color image; ; any of the bands can be put in a single color. The band combination which is used can be changed to highlight the desired feature or phenomena. Microwave Spaceborne Radar Radio Medical - MRI stronomy Weather Radar stronomy Radiotelescope Gamma Radio Julian Moger 3

4 Electromagnetic Waves Sinusoidal Model mplitude Electric field Wavelength Length of one cycle Frequency Hz = cycles per second Electromagnetic Waves Frequency is the number of wavelength passing a point per second dis tan ce velocity = time velocity = frequency wavelength = [ s ][ m] = [ ms 1 1 ] c = fλ Energy of Electromagnetic Radiation Energy is proportional to frequency Energy = constant x frequency OR E = hf Frequency, Wavelength & Energy Different regions of the electromagnetic spectrum are measured in different ways Where h is Plank s s constant h = x Js Visible light: Calculate the energy of a 400 nm photon Early experiments describe light as a wave Quoted in meters Julian Moger 4

5 Radio waves: Calculate the wavelength of 97.7 MHz Measured via oscillations of electrons in conductors Quoted in Hz s: Produced using electric potential Quoted in kev Calculate the frequency of a 50 kev x- ray photon ev = the energy of one electron accelerate by one volt E = hf Ionizing Radiation Radiation with sufficient energy to cause ionization Binding energy of outermost electron to atoms ~ ev Summary Electromagnetic Waves Properties of Electromagnetic Spectrum Inverse Square Law Julian Moger 5

Energy. Mechanical Energy

Energy. Mechanical Energy Principles of Imaging Science I (RAD119) Electromagnetic Radiation Energy Definition of energy Ability to do work Physicist s definition of work Work = force x distance Force acting upon object over distance

More information

Section 1 Electromagnetic Waves

Section 1 Electromagnetic Waves Section 1 Electromagnetic Waves What are electromagnetic waves? What do microwaves, cell phones, police radar, television, and X-rays have in common? All of them use electromagnetic waves Electromagnetic

More information

The Nature of Light. As a particle

The Nature of Light. As a particle The Nature of Light Light is radiant energy. Travels very fast 300,000 km/sec! Can be described either as a wave or as a particle traveling through space. As a wave A small disturbance in an electric field

More information

physics 112N electromagnetic waves

physics 112N electromagnetic waves physics 112N electromagnetic waves electromagnetic waves? Faraday s law told us that time-varying magnetic fields generate electric fields James Clerk Maxwell found that time-varying electric fields generate

More information

Electromagnetic Radiation

Electromagnetic Radiation Activity 17 Electromagnetic Radiation Why? Electromagnetic radiation, which also is called light, is an amazing phenomenon. It carries energy and has characteristics of both particles and waves. We can

More information

Light. Light. Overview. In-class activity. What are waves? In this section: PSC 203. What is it? Your thoughts?

Light. Light. Overview. In-class activity. What are waves? In this section: PSC 203. What is it? Your thoughts? Light PSC 203 Overview In this section: What is light? What is the EM Spectrum? How is light created? What can we learn from light? In-class activity Discuss your answers in groups of 2 Think of as many

More information

Chapter 2 Electromagnetic Radiation

Chapter 2 Electromagnetic Radiation Chapter 2 Electromagnetic Radiation Bohr demonstrated that information about the structure of hydrogen could be gained by observing the interaction between thermal energy (heat) and the atom. Many analytical

More information

Electromagnetic Radiation and Atomic Spectra POGIL

Electromagnetic Radiation and Atomic Spectra POGIL Name _Key AP Chemistry Electromagnetic Radiation and Atomic Spectra POGIL Electromagnetic Radiation Model 1: Characteristics of Waves The figure above represents part of a wave. The entire wave can be

More information

Electromagnetic Radiation and Atomic Physics

Electromagnetic Radiation and Atomic Physics Electromagnetic Radiation and Atomic Physics Properties of Electrons, Protons, and Neutrons (The Main Constituents of Ordinary Matter) Mass Electrons have a mass of 9.11 10-31 kg. The mass of a proton

More information

21 The Nature of Electromagnetic Waves

21 The Nature of Electromagnetic Waves 21 The Nature of Electromagnetic Waves When we left off talking about the following circuit: I E v = c B we had recently closed the switch and the wire was creating a magnetic field which was expanding

More information

6.1 Electromagnetic Waves

6.1 Electromagnetic Waves 6.1 Electromagnetic Waves electromagnetic radiation can be described as a harmonic wave in either time or distance waves are characterized by their period, frequency, wavelength and wave number Planck's

More information

ELECTROMAGNETIC WAVES

ELECTROMAGNETIC WAVES ELECTROMAGNETIC WAVES physicswithikgogia Page 1 www.physicsbeckons.wordpress.com physicswithikgogia Page 2 physicswithikgogia Page 3 physicswithikgogia Page 4 physicswithikgogia Page 5 Properties: 1. Variations

More information

Electromagnetic Radiation (including visible light)

Electromagnetic Radiation (including visible light) An expert is a man who has made all the mistakes, which can be made in a narrow field. Neils Bohr Electromagnetic Radiation (including visible light) Behaves like a particle. light particles are called

More information

Electromagnetic Spectrum

Electromagnetic Spectrum Electromagnetic Spectrum Why do some things have colors? What makes color? Why do fast food restaurants use red lights to keep food warm? Why don t they use green or blue light? Why do X-rays pass through

More information

Practice Problems (Set #1) Properties of Electromagnetic Radiation. 1. Why don't we notice the wave nature of matter in our everyday experience?

Practice Problems (Set #1) Properties of Electromagnetic Radiation. 1. Why don't we notice the wave nature of matter in our everyday experience? Practice Problems (Set #1) Properties of Electromagnetic Radiation 1. Why don't we notice the wave nature of matter in our everyday experience? Since matter has huge mass, the wavelength will be very large

More information

Lecture 1. The nature of electromagnetic radiation.

Lecture 1. The nature of electromagnetic radiation. Lecture 1. The nature of electromagnetic radiation. 1. Basic introduction to the electromagnetic field: Dual nature of electromagnetic radiation Electromagnetic spectrum. Basic radiometric quantities:

More information

CHM111 Lab Atomic Emission Spectroscopy Grading Rubric

CHM111 Lab Atomic Emission Spectroscopy Grading Rubric Name Team Name CHM111 Lab Atomic Emission Spectroscopy Grading Rubric Criteria Points possible Points earned Lab Performance Printed lab handout and rubric was brought to lab 3 Followed procedure correctly

More information

Overview. What is EMR? Electromagnetic Radiation (EMR) LA502 Special Studies Remote Sensing

Overview. What is EMR? Electromagnetic Radiation (EMR) LA502 Special Studies Remote Sensing LA502 Special Studies Remote Sensing Electromagnetic Radiation (EMR) Dr. Ragab Khalil Department of Landscape Architecture Faculty of Environmental Design King AbdulAziz University Room 103 Overview What

More information

From lowest energy to highest energy, which of the following correctly orders the different categories of electromagnetic radiation?

From lowest energy to highest energy, which of the following correctly orders the different categories of electromagnetic radiation? From lowest energy to highest energy, which of the following correctly orders the different categories of electromagnetic radiation? From lowest energy to highest energy, which of the following correctly

More information

nm cm meters VISIBLE UVB UVA Near IR 200 300 400 500 600 700 800 900 nm

nm cm meters VISIBLE UVB UVA Near IR 200 300 400 500 600 700 800 900 nm Unit 5 Chapter 13 Electrons in the Atom Electrons in the Atom (Chapter 13) & The Periodic Table/Trends (Chapter 14) Niels Bohr s Model Recall the Evolution of the Atom He had a question: Why don t the

More information

Today. Electromagnetic Radiation. Light & beyond. Thermal Radiation. Wien & Stefan-Boltzmann Laws

Today. Electromagnetic Radiation. Light & beyond. Thermal Radiation. Wien & Stefan-Boltzmann Laws Today Electromagnetic Radiation Light & beyond Thermal Radiation Wien & Stefan-Boltzmann Laws 1 Electromagnetic Radiation aka Light Properties of Light are simultaneously wave-like AND particle-like Sometimes

More information

Episode 314: Electromagnetic radiation

Episode 314: Electromagnetic radiation Episode 314: Electromagnetic radiation This episode extends students understanding of the nature of different types of electromagnetic radiation, and considers their shared nature. Summary Demonstration:

More information

Examples of Uniform EM Plane Waves

Examples of Uniform EM Plane Waves Examples of Uniform EM Plane Waves Outline Reminder of Wave Equation Reminder of Relation Between E & H Energy Transported by EM Waves (Poynting Vector) Examples of Energy Transport by EM Waves 1 Coupling

More information

Chapter 22 Electromagnetic Waves. Copyright 2010 Pearson Education, Inc.

Chapter 22 Electromagnetic Waves. Copyright 2010 Pearson Education, Inc. Chapter 22 Electromagnetic Waves The Production of Electromagnetic Waves Any time an electric charge is accelerated, it will radiate electromagnetic waves. The Production of Electromagnetic Waves An electromagnetic

More information

Chapter 27 Early Quantum Physics and the Photon

Chapter 27 Early Quantum Physics and the Photon Chapter 27 Early Quantum Physics and the Photon 1. A problem with the classical theory for radiation from a blackbody was that the theory predicted too much radiation in the wavelengths. A. ultraviolet

More information

Production of X-rays. Radiation Safety Training for Analytical X-Ray Devices Module 9

Production of X-rays. Radiation Safety Training for Analytical X-Ray Devices Module 9 Module 9 This module presents information on what X-rays are and how they are produced. Introduction Module 9, Page 2 X-rays are a type of electromagnetic radiation. Other types of electromagnetic radiation

More information

WAVES AND PARTICLES. (v) i.e (vi) The potential difference required to bring an electron of wavelength to rest

WAVES AND PARTICLES. (v) i.e (vi) The potential difference required to bring an electron of wavelength to rest WAVES AND PARTICLES 1. De Broglie wavelength associated with the charges particles (i) The energy of a charged particle accelerated through potential difference q = charge on the particel (ii) Momentum

More information

Q1. The diagram below shows the range of wavelengths and frequencies for all the types of radiation in the electromagnetic spectrum.

Q1. The diagram below shows the range of wavelengths and frequencies for all the types of radiation in the electromagnetic spectrum. Q. The diagram below shows the range of wavelengths and frequencies for all the types of radiation in the electromagnetic spectrum. X rays, which have frequencies in the range 0 8 0 2 Hz are already marked

More information

Example: Water wave. Water just moves up and down Wave travels and can transmit energy (tsunami)

Example: Water wave. Water just moves up and down Wave travels and can transmit energy (tsunami) Waves R Us What are Waves? Waves: moving disturbances that transmit energy without the physical transport of material - waves in a pool or waves in a wheat field or waves of people in a football field.

More information

MAKING SENSE OF ENERGY Electromagnetic Waves

MAKING SENSE OF ENERGY Electromagnetic Waves Adapted from State of Delaware TOE Unit MAKING SENSE OF ENERGY Electromagnetic Waves GOALS: In this Part of the unit you will Learn about electromagnetic waves, how they are grouped, and how each group

More information

11/15/2016. Electromagnetic (EM) waves are waves caused by oscillations occurring simultaneously in electric and magnetic fields

11/15/2016. Electromagnetic (EM) waves are waves caused by oscillations occurring simultaneously in electric and magnetic fields Electromagnetic (EM) waves are waves caused by oscillations occurring simultaneously in electric and magnetic fields A 2D transverse wave The EM and Visible Spectra They DO NOT require any medium in order

More information

Light as a Wave. The Nature of Light. EM Radiation Spectrum. EM Radiation Spectrum. Electromagnetic Radiation

Light as a Wave. The Nature of Light. EM Radiation Spectrum. EM Radiation Spectrum. Electromagnetic Radiation The Nature of Light Light and other forms of radiation carry information to us from distance astronomical objects Visible light is a subset of a huge spectrum of electromagnetic radiation Maxwell pioneered

More information

Chapter 25 Electromagnetic Waves

Chapter 25 Electromagnetic Waves Chapter 25 Electromagnetic Waves Units of Chapter 25 The Production of Electromagnetic Waves The Propagation of Electromagnetic Waves The Electromagnetic Spectrum Energy and Momentum in Electromagnetic

More information

Lecture 8: Radiation Spectrum. Radiation. Electromagnetic Radiation

Lecture 8: Radiation Spectrum. Radiation. Electromagnetic Radiation Lecture 8: Radiation Spectrum The information contained in the light we receive is unaffected by distance The information remains intact so long as the light doesn t run into something along the way Since

More information

Calculating particle properties of a wave

Calculating particle properties of a wave Calculating particle properties of a wave A light wave consists of particles (photons): The energy E of the particle is calculated from the frequency f of the wave via Planck: E = h f (1) A particle can

More information

Light is a type of electromagnetic (EM) radiation, and light has energy. Many kinds of light exist. Ultraviolet (UV) light causes skin to tan or burn.

Light is a type of electromagnetic (EM) radiation, and light has energy. Many kinds of light exist. Ultraviolet (UV) light causes skin to tan or burn. Light and radiation Light is a type of electromagnetic (EM) radiation, and light has energy. Many kinds of light exist. Ultraviolet (UV) light causes skin to tan or burn. Infrared (IR) light is used in

More information

AS Revision questions Quantum Phenomena and Electricity

AS Revision questions Quantum Phenomena and Electricity Q1. (a) State what happens in an atom when line spectra are produced. Electrons move from one energy level (or orbit) to a higher one (1 mark) when they absorb energy from an incoming photon or interact

More information

Chapter 6 Electronic Structure of Atoms

Chapter 6 Electronic Structure of Atoms Chapter 6 Electronic Structure of Atoms 1. Electromagnetic radiation travels through vacuum at a speed of m/s. (a). 6.626 x 26 (b). 4186 (c). 3.00 x 8 (d). It depends on wavelength Explanation: The speed

More information

Physics 2101 Section 3 Apr 14th Announcements: Quiz Friday Midterm #4, April Midterm #4,

Physics 2101 Section 3 Apr 14th Announcements: Quiz Friday Midterm #4, April Midterm #4, Physics 2101 Section 3 Apr 14 th Announcements: Quiz Friday Midterm #4, April 28 th Final: May 11 th-7:30am Class Website: 6 pm Make up Final: May 15 th -7:30am http://www.phys.lsu.edu/classes/spring2010/phys2101

More information

Lecture 7: Light Waves. Newton s Laws of Motion (1666) Newton s First Law of Motion

Lecture 7: Light Waves. Newton s Laws of Motion (1666) Newton s First Law of Motion Lecture 7: Light Waves Isaac Newton (1643-1727) was born in the year Galileo died He discovered the Law of Gravitation in 1665 He developed the Laws of Mechanics that govern all motions In order to solve

More information

People s Physics book

People s Physics book The Big Idea Quantum Mechanics, discovered early in the 20th century, completely shook the way physicists think. Quantum Mechanics is the description of how the universe works on the very small scale.

More information

Geomorphology G322 Introduction to Aerial Photographs

Geomorphology G322 Introduction to Aerial Photographs Geomorphology G322 Introduction to Aerial Photographs I. Introduction to Air Photos A. Aerial photographs are acquired by airpcraft especially equipped with cameras and view ports. 1. Early Work... Balloon-based

More information

Non-Ionizing Electromagnetic Radiation

Non-Ionizing Electromagnetic Radiation This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike License. Your use of this material constitutes acceptance of that license and the conditions of use of materials on this

More information

Electromagnetic Radiation

Electromagnetic Radiation Forms of Energy There are many types of energy. Kinetic energy is the energy of motion. Potential energy is energy that results from position, such as the energy in water going over a dam. Electrical energy

More information

Principles of Technology CH 12 Wave and Sound 1 Name

Principles of Technology CH 12 Wave and Sound 1 Name Principles of Technology CH 12 Wave and Sound 1 Name KEY OBJECTIVES At the conclusion of this chapter you will be able to: Define the terms periodic wave, wave motion, transverse wave, longitudinal wave,

More information

Investigating electromagnetic radiation

Investigating electromagnetic radiation Investigating electromagnetic radiation Announcements: First midterm is 7:30pm on 2/17/09 Problem solving sessions M3-5 and T3-4,5-6. Homework due at 12:50pm on Wednesday. We are covering Chapter 4 this

More information

Introduction t o to Wireless Wireless Communication

Introduction t o to Wireless Wireless Communication Introduction to Wireless Communication History of wireless communication Guglielmo Marconi invented the wireless telegraph in 1896 Communication by encoding alphanumeric characters in analog signal Sent

More information

Grade 8 Science Chapter 4 Notes

Grade 8 Science Chapter 4 Notes Grade 8 Science Chapter 4 Notes Optics the science that deals with the properties of light. Light a form of energy that can be detected by the human eye. The History of Optics (3 Scientists): 1. Pythagoras

More information

IGCSE REVISION QUESTIONS

IGCSE REVISION QUESTIONS IGCSE REVISION QUESTIONS These questions are based on the EdExcel IGCSE Physics (4420) specification. The specification is broken up into seven sections: 1.) Forces and motion 2.) Electricity 3.) Waves

More information

I. C O N T E N T S T A N D A R D S

I. C O N T E N T S T A N D A R D S Introductory Physics, High School Learning Standards for a Full First-Year Course I. C O N T E N T S T A N D A R D S 4. Waves Central Concept: Waves carry energy from place to place without the transfer

More information

Chapter 6 Electromagnetic Radiation and the Electronic Structure of the Atom

Chapter 6 Electromagnetic Radiation and the Electronic Structure of the Atom Chapter 6 In This Chapter Physical and chemical properties of compounds are influenced by the structure of the molecules that they consist of. Chemical structure depends, in turn, on how electrons are

More information

Chapter 6 Electronic Structure and the Periodic Table

Chapter 6 Electronic Structure and the Periodic Table Chapter 6 Electronic Structure and the Periodic Table MULTIPLE CHOICE 1. The Navy uses electromagnetic radiation of extremely long wavelengths to communicate with submerged submarines. The Navy's ELF (Extremely

More information

Light as a wave. VCE Physics.com. Light as a wave - 1

Light as a wave. VCE Physics.com. Light as a wave - 1 Light as a wave Huygen s wave theory Newton s corpuscular theory Young s double slit experiment Double slit interference Diffraction Single slit interference The electromagnetic nature of light The electromagnetic

More information

Electromagnetic (EM) waves. Electric and Magnetic Fields. L 30 Electricity and Magnetism [7] James Clerk Maxwell (1831-1879)

Electromagnetic (EM) waves. Electric and Magnetic Fields. L 30 Electricity and Magnetism [7] James Clerk Maxwell (1831-1879) L 30 Electricity and Magnetism [7] ELECTROMAGNETIC WAVES Faraday laid the groundwork with his discovery of electromagnetic induction Maxwell added the last piece of the puzzle Heinrich Hertz made the experimental

More information

The Nature of Electromagnetic Radiation

The Nature of Electromagnetic Radiation II The Nature of Electromagnetic Radiation The Sun s energy has traveled across space as electromagnetic radiation, and that is the form in which it arrives on Earth. It is this radiation that determines

More information

PS-7.2 Compare the nature and properties of transverse and longitudinal/compressional mechanical waves.

PS-7.2 Compare the nature and properties of transverse and longitudinal/compressional mechanical waves. PS-7.1 Illustrate ways that the energy of waves is transferred by interaction with matter (including transverse and longitudinal /compressional waves). Understand that a wave is a repeating disturbance

More information

Since we will be studying electromagnetic waves, let s review some general features of waves:

Since we will be studying electromagnetic waves, let s review some general features of waves: The Nature of Waves Since we will be studying electromagnetic waves, let s review some general features of waves: 1. A wave is a traveling disturbance. 2. A wave carries energy from place to place. The

More information

Bronx High School of Science Regents Physics

Bronx High School of Science Regents Physics Bronx High School of Science Regents Physics 1. Orange light has a frequency of 5.0 10 14 hertz in a vacuum. What is the wavelength of this light? (A) 1.5 10 23 m (C) 6.0 10 7 m (B) 1.7 10 6 m (D) 2.0

More information

Farbe. Physics of Color

Farbe. Physics of Color Farbe Physics of Color Light Basic Properties visible light is electromagnetic radiation in a particular region of the entire spectrum distinguishing criterion: its frequency ~780 380 nm 380 780 THz AM

More information

Physics 30 Worksheet # 14: Michelson Experiment

Physics 30 Worksheet # 14: Michelson Experiment Physics 30 Worksheet # 14: Michelson Experiment 1. The speed of light found by a Michelson experiment was found to be 2.90 x 10 8 m/s. If the two hills were 20.0 km apart, what was the frequency of the

More information

Sample Exercise 6.1 Concepts of Wavelength and Frequency

Sample Exercise 6.1 Concepts of Wavelength and Frequency Sample Exercise 6.1 Concepts of Wavelength and Frequency Two electromagnetic waves are represented in the margin. (a) Which wave has the higher frequency? (b) If one wave represents visible light and the

More information

3-1. True or False: Different colors of light are waves with different amplitudes. a.) True b.) False X

3-1. True or False: Different colors of light are waves with different amplitudes. a.) True b.) False X 3-1. True or False: Different colors of light are waves with different amplitudes. a.) True b.) False X 3-2. True or False: Different colors of light are waves with different wavelengths. a.) True X b.)

More information

ELECTROMAGNETIC SPECTRUM

ELECTROMAGNETIC SPECTRUM ELECTROMAGNETIC SPECTRUM Brief review: Water and sound waves transfer energy from one place to another- they require a medium through which to travel. They are mechanical waves. Electric field-region in

More information

EM Waves Practice Problems

EM Waves Practice Problems EM Waves Practice Problems PSI AP Physics B Name Multiple Choice 1. Which of the following theories can explain the bending of waves behind obstacles into shadow region? (A) Particle theory of light (B)

More information

A It is halved. B It is doubled. C It is quadrupled. D It remains the same.

A It is halved. B It is doubled. C It is quadrupled. D It remains the same. WAVES UNIT REVIEW EN: CALIFORNIA STATE QUESTIONS: 1. A sound wave is produced in a metal cylinder by striking one end. Which of the following occurs as the wave travels along the cylinder? A Its amplitude

More information

Use the following image to answer the next question. 1. Which of the following rows identifies the electrical charge on A and B shown above?

Use the following image to answer the next question. 1. Which of the following rows identifies the electrical charge on A and B shown above? Old Science 30 Physics Practice Test A on Fields and EMR Test Solutions on the Portal Site Use the following image to answer the next question 1. Which of the following rows identifies the electrical charge

More information

#1 Electromagnetic Spectrum Intro

#1 Electromagnetic Spectrum Intro Go here for text on each section http://missionscience.nasa.gov/ems/index.html #1 Electromagnetic Spectrum Intro Go here for the video http://missionscience.nasa.gov/ems/emsvideo_01intro.html a. How are

More information

Introduction to Spectroscopy.

Introduction to Spectroscopy. Introduction to Spectroscopy. ARCHIMEJ TECHNOLOGY The SPECTROSCOPY 2.0 Company To understand what the core of our project is about, you need to grasp some basic notions of optical spectroscopy. This lesson

More information

13- What is the maximum number of electrons that can occupy the subshell 3d? a) 1 b) 3 c) 5 d) 2

13- What is the maximum number of electrons that can occupy the subshell 3d? a) 1 b) 3 c) 5 d) 2 Assignment 06 A 1- What is the energy in joules of an electron undergoing a transition from n = 3 to n = 5 in a Bohr hydrogen atom? a) -3.48 x 10-17 J b) 2.18 x 10-19 J c) 1.55 x 10-19 J d) -2.56 x 10-19

More information

Astronomy 110 Homework #05 Assigned: 02/13/2007 Due: 02/20/2007. Name: (Answer Key)

Astronomy 110 Homework #05 Assigned: 02/13/2007 Due: 02/20/2007. Name: (Answer Key) Astronomy 110 Homework #05 Assigned: 02/13/2007 Due: 02/20/2007 Name: (Answer Key) Directions: Listed below are twenty (20) multiple-choice questions based on the material covered by the lectures thus

More information

Chemistry 102 Summary June 24 th. Properties of Light

Chemistry 102 Summary June 24 th. Properties of Light Chemistry 102 Summary June 24 th Properties of Light - Energy travels through space in the form of electromagnetic radiation (EMR). - Examples of types of EMR: radio waves, x-rays, microwaves, visible

More information

Name Date Class ELECTRONS IN ATOMS. Standard Curriculum Core content Extension topics

Name Date Class ELECTRONS IN ATOMS. Standard Curriculum Core content Extension topics 13 ELECTRONS IN ATOMS Conceptual Curriculum Concrete concepts More abstract concepts or math/problem-solving Standard Curriculum Core content Extension topics Honors Curriculum Core honors content Options

More information

Name: Exampro GCSE Physics. Class: P1 Waves Self Study Questions - Higher tier. Author: Date: Time: 74. Marks: 74. Comments: Page 1 of 27

Name: Exampro GCSE Physics. Class: P1 Waves Self Study Questions - Higher tier. Author: Date: Time: 74. Marks: 74. Comments: Page 1 of 27 Exampro GCSE Physics P Waves Self Study Questions - Higher tier Name: Class: Author: Date: Time: 74 Marks: 74 Comments: Page of 27 Q. All radio waves travel at 300 000 000 m/s in air. (i) Give the equation

More information

Light bulbs. Lightbulbs. How does a light bulb work? Light bulbs. Midterm 2 results. End of semester grade policy. Ave: 31.8/40.

Light bulbs. Lightbulbs. How does a light bulb work? Light bulbs. Midterm 2 results. End of semester grade policy. Ave: 31.8/40. Light bulbs Lightbulbs How many scientists does it take to change a lightbulb? Undergraduates: None right light - hurts... must go back to bed. Postgraduates: Funding for a new lightbulb ran out six months

More information

Chapter Test B. Chapter: Arrangement of Electrons in Atoms. possible angular momentum quantum numbers? energy level? a. 4 b. 8 c. 16 d.

Chapter Test B. Chapter: Arrangement of Electrons in Atoms. possible angular momentum quantum numbers? energy level? a. 4 b. 8 c. 16 d. Assessment Chapter Test B Chapter: Arrangement of Electrons in Atoms PART I In the space provided, write the letter of the term or phrase that best completes each statement or best answers each question

More information

MECHANICS PROJECTILE MOTION

MECHANICS PROJECTILE MOTION 1 MECHANICS PROJECTILE MOTION When an object is in free fall, the object is at an acceleration of 10m/s down Displacement is the straight line from start to finish in that direction Projectile: An object

More information

CHAPTER 14 WAVE & Sound

CHAPTER 14 WAVE & Sound CHAPTER 14 WAVE & Sound COURSE CONTENT Properties of waves Definition Types of waves Wavelength Amplitude Frequency Waves are everywhere in nature Sound waves, visible light waves, radio waves, microwaves,

More information

The Electromagnetic Spectrum

The Electromagnetic Spectrum The Electromagnetic Spectrum 1 Look around you. What do you see? You might say "people, desks, and papers." What you really see is light bouncing off people, desks, and papers. You can only see objects

More information

Physics Open House. Faraday's Law and EM Waves Change in the magnetic field strength in coils generates a current. Electromagnetic Radiation

Physics Open House. Faraday's Law and EM Waves Change in the magnetic field strength in coils generates a current. Electromagnetic Radiation Electromagnetic Radiation (How we get most of our information about the cosmos) Examples of electromagnetic radiation: Light Infrared Ultraviolet Microwaves AM radio FM radio TV signals Cell phone signals

More information

Lecture 2: Radiation/Heat in the atmosphere

Lecture 2: Radiation/Heat in the atmosphere Lecture 2: Radiation/Heat in the atmosphere TEMPERATURE is a measure of the internal heat energy of a substance. The molecules that make up all matter are in constant motion. By internal heat energy, we

More information

3. What are electromagnetic waves? Electromagnetic waves are transverse waves that have some electrical properties and some magnetic properties.

3. What are electromagnetic waves? Electromagnetic waves are transverse waves that have some electrical properties and some magnetic properties. CHAPTER 3 - THE ELECTROMAGNETIC SPECTRUM 3-1 The Nature of Electromagnetic Waves 1. What do all mechanical waves such as sound waves have in common? All mechanical waves such as sound waves transfer energy

More information

CHAPTER 2: Electromagnetic Radiation Principles

CHAPTER 2: Electromagnetic Radiation Principles CHAPTER 2: Electromagnetic Radiation Principles REFERENCE: Remote Sensing of the Environment John R. Jensen (2007) Second Edition Pearson Prentice Hall DETECTING THE REMOTE SIGNAL 1 Electromagnetic Energy

More information

Planck s constant. The value of Planck s constant is

Planck s constant. The value of Planck s constant is 852 CHAPTER 25. Electromagnetic Induction and Electromagnetic Waves Increasing light intensity The photo at very low light levels shows individual points, as if particles are arriving at the detector.

More information

Amplitude Y is the maximum value of the wave variable ( displacement in this case ).

Amplitude Y is the maximum value of the wave variable ( displacement in this case ). NATURE OF VISIBLE LIGHT: Our current knowledge is that light exhibits a dual nature or behavior. It behaves as electromagnetic ( EM for short ) waves or as a particles ( photons ). General description

More information

Week 13 - Electromagnetic Waves

Week 13 - Electromagnetic Waves Week 13 - Electromagnetic Waves November 25, 2012 Exercise 13.1: Ultraviolet Radiation There are two categories of ultra-violet light. Ultraviolet A (UVA) has a wavelength ranging from 320 nm to 400 nm.

More information

Solar Matters III Teacher Page

Solar Matters III Teacher Page Solar Matters III Teacher Page Electromagnetic Spectrum Student Objective The student: will know that the Sun s energy is transferred to Earth by electromagnetic waves will understand that there are eight

More information

Q1. The diagram below shows the range of wavelengths and frequencies for all the types of radiation in the electromagnetic spectrum.

Q1. The diagram below shows the range of wavelengths and frequencies for all the types of radiation in the electromagnetic spectrum. Q. The diagram below shows the range of wavelengths and frequencies for all the types of radiation in the electromagnetic spectrum. X-rays, which have frequencies in the range 0 8 0 2 Hz are already marked

More information

Remote Sensing. Vandaag. Voordelen Remote Sensing Wat is Remote Sensing? Vier elementen Remote Sensing systeem

Remote Sensing. Vandaag. Voordelen Remote Sensing Wat is Remote Sensing? Vier elementen Remote Sensing systeem Remote Sensing 1 Vandaag Voordelen Remote Sensing Wat is Remote Sensing? Vier elementen Remote Sensing systeem 2 Nederland Vanaf 700 km hoogte Landsat TM mozaïek 3 Europa vanaf 36000 km hoogte 4 5 Mount

More information

1. According to quantum theory, light energy is carried in discrete units called. A) protons B) photons C) photoelectrons D) quarks

1. According to quantum theory, light energy is carried in discrete units called. A) protons B) photons C) photoelectrons D) quarks Name: Photon Energy. ccording to quantum theory, light energy is carried in discrete units called. ) protons ) photons ) photoelectrons ) quarks 2. In which part of the electromagnetic spectrum does a

More information

D.S. Boyd School of Earth Sciences and Geography, Kingston University, U.K.

D.S. Boyd School of Earth Sciences and Geography, Kingston University, U.K. PHYSICAL BASIS OF REMOTE SENSING D.S. Boyd School of Earth Sciences and Geography, Kingston University, U.K. Keywords: Remote sensing, electromagnetic radiation, wavelengths, target, atmosphere, sensor,

More information

Tools of Astronomy Notes

Tools of Astronomy Notes Tools of Astronomy Notes Light is a form of electromagnetic radiation. Scientists call the light you can see visible light. If you shine white light through a prism, the light spreads out to make a range

More information

Astronomy 153 Lab 3: The Light Spectrum

Astronomy 153 Lab 3: The Light Spectrum Astronomy 153 Lab 3: The Light Spectrum Solar Radiation Incident on the Earth Intensity v. Wavelength Image By: http://wiki.naturalfrequency.com/wiki/solar_radiation Astronomers use the light, or radiation,

More information

Electromagnetic waves. Generation of EM waves

Electromagnetic waves. Generation of EM waves Electromagnetic waves Lecture topics Generation of EM waves Terminology Wave and particle models of EM radiation EM spectrum Generation of EM waves Acceleration of an electrical charge EM wavelength depends

More information

CHAPTER 6: ANSWERS TO ASSIGNED PROBLEMS Hauser- General Chemistry I revised 8/03/08

CHAPTER 6: ANSWERS TO ASSIGNED PROBLEMS Hauser- General Chemistry I revised 8/03/08 CHAPTER 6: ANSWERS TO ASSIGNED PROBLEMS Hauser- General Chemistry I revised 8/03/08 6.9 What are the basic SI units for? (a) the wavelength of light meters, although colors are usually reported in 3 digit

More information

Objectives. Electromagnetic Waves 386 CHAPTER 9 RADIATION

Objectives. Electromagnetic Waves 386 CHAPTER 9 RADIATION Objectives Explain the nature and source of electromagnetic radiation. Explain how a changing electric field can produce an electromagnetic wave. Explain how the wavelength, frequency, and speed of an

More information

Map to Help Room (G2B90)

Map to Help Room (G2B90) Map to Help Room (G2B90) Lecture room Help room Homework Turn in your homework at the beginning of class next lecture. It will be collected shortly after lecture starts. Put your homework in the appropriate

More information

Chapter 2: Electromagnetic Radiation Radiant Energy I

Chapter 2: Electromagnetic Radiation Radiant Energy I Chapter 2: Electromagnetic Radiation Radiant Energy I Goals of Period 2 Section 2.1: To introduce electromagnetic radiation Section 2.2: To discuss the wave model of radiant energy Section 2.3: To describe

More information

Newton s laws of motion and gravity

Newton s laws of motion and gravity Newton s laws of motion and gravity 1. Every body continues in a state of rest or uniform motion (constant velocity) in a straight line unless acted on by a force. (A deeper statement of this law is that

More information