Physics First: Wave Energy Units
Examples of all types of waves are found in nature. Our understanding of the physical world is not complete until we understand the properties and behaviors of waves. Mechanical waves require a material "medium" through which to travel, electromagnetic waves do not.
Teaching About Waves and Wave Energy (10)
Lesson Plans:
This is a unique, standards-based unit of instruction on Waves created by a high school teacher to be used with PhET interactive simulations on wave motion. It includes comprehensive lesson plans, lecture presentations, and assessments with answer keys. Be sure not to miss the "Clicker Questions" -- great introductory material. NOTE: Only registered PhET users can access teacher-contributed materials, but registration is free and easy.
Level: Grades 9-12
Cross-disciplinary resource blends physics, earth science, and global history to get students excited about the science of tsunamis. It is a highly engaging way to introduce your students to the basic wave properties of frequency, amplitude, and periodicity. They use real-time data to see how various global agencies monitor for tsunami activity, then develop a "preparedness plan" using evidence from the data they collected. Most appropriate for grades 8-12, but could be adapted for Grades 6-7.
Level: Grades 6-12
Duration: 5-7
Activities:
From research in physics education, there is increasing awareness that students come into a physics class with firmly held beliefs that cannot be ignored. These tutorials use hands-on activities and probing questions to draw out misconceptions and facilitate learning. They are designed for cooperative learning groups, with complete sets of student activities and problems. Accompanying solutions are to be distributed to groups before they leave class, thus giving immediate feedback.
Level: High School Physics
If you have not yet used video analysis software with your students, be prepared for a paradigm shift in your teaching! This resource provides free software called "Tracker", developed to help students closely analyze the motion of objects in a short video clip. It also allows them to create dynamical models that overlay the video to see how well the model matches the real world. Detailed instructions are provided. And it's free.
References and Collections:
This award-winning website offers animation-based tutorials on concepts relating to wave phenomena, sound waves, simple and coupled oscillators, harmonic motion, resonance, superposition, acoustics, and double-slit interference. Each topic features simple text explanations, all supported with animations that illustrate the concept.
Level: Grades 9-12
A must-read article from Science magazine, this item summarizes the research efforts of the PhET project on the use of interactive simulations in the physics classroom. Results indicate that concept mastery is measurably improved when students explore simulated physical processes in addition to traditional labs. Use of simulations was also correlated to higher student motivation and active involvement in the learning process.
Content Support For Teachers:
A straightforward tutorial suitable for crossover teachers or K-8 physical science teachers who would like a refresher on the topic of waves. This is part of the respected Physics Classroom tutorial collection, and covers wave categories, properties and behavior of waves, and how waves transport energy.
New and crossover teachers often appreciate a way to "see" physics beyond the pages of a textbook. This interactive tutorial covers every topic typically studied in an introduction to Waves. There are 20 sequenced tutorials, each with a discussion of one focused idea, a Java simulation that depicts that idea, and self-guided questions at the end.
Don't be scared off by the title of this item. It's a fascinating resource that features a "thematic search engine" for locating information and examples of sound, sound waves, acoustics, hearing, and other related topics. Each topic is accompanied by audio clips from the library of the World Soundscape Project. For example, the topic "Hearing Loss" contains an audio simulation of normal and impaired hearing as a result of noise exposure. Students will enjoy playing around with this one.
Level: Grades 6-12
Assessment:
This PhET Gold Star-winning resource is a set of 60+ Power Point concept questions on the topic of waves, available for free download. They were created by a high school physics teacher to be used with three PhET simulations: Wave on a String, Fourier Analysis, and Sound. Concept questions are designed to introduce a topic and probe student understanding BEFORE formal instruction. This method has been correlated with improved learner outcomes in studies conducted by physics education researchers. NOTE: You must be a registered PhET user to access this resource. Registration is free, easy, and well worth your time.
Level: 9-12
Types of Mechanical Waves (11)
Lesson Plans:
Full guidelines for set-up of eight classroom activities designed to introduce students to various types of waves and the language used to describe them. Students learn about transverse, longitudinal, electromagnetic, and water waves through simple and practical experiments.
Level: Grades 8-12
This lesson integrates a short video, "Making Big Waves", with a detailed lesson plan on using Slinky springs to model transverse and longitudinal waves. The resource includes discussion questions and instructional tips for implementing the activity effectively.
Level: Grades 6-10
Duration: 50 minutes
A great way to spark student interest in wave motion is through the study of tsunamis. This magazine article, which appeared in The Physics Teacher in 2006, provides a step-by-step blueprint for constructing your own low-cost tsunami tank for experimenting in the classroom. Related classroom activities capture the essential physics of tsunamis.
Level: Grades 8-12
Activities:
This simple, yet highly visual experiment uses dynamics trolleys, springs, and spring holders to model a transverse and a longitudinal wave. The models are easy enough for students to set up, but allow exploration of complex concepts, such as how this dispersive system differs from a continuous wave medium like a rope or slinky (see experiment below for a companion activity).
Level: Grades 9-12
Duration: 30 Minutes
A Slinky spring is one of the best ways to model both transverse and longitudinal waves. Teaching tips in this web site explain how to get the best results. Try teaming this experiment with the one above that uses dynamics trolleys connected by springs. Students can compare/contrast the wave motion in a continuous versus a dispersive system (trolleys).
Level: Grades 6-12
Duration: 30 minutes
This set of 3 video clips show wave pulses on a Slinky spring. The first depicts a transverse wave pulse and its reflection off an fixed end. The second shows a longitudinal pulse, and the third shows two wave pulses passing over each other. For free software tools to do computer analysis of these videos frame-by-frame, see the "Tracker Video Analysis" item below.
Level: Grades 6-12
Mechanical waves can be modeled well through computer simulations that depict the motion of particles as the wave disturbance travels through a medium. This web-based tutorial for grades 6-12, developed by the University of Utah's ASPIRE Lab, is an excellent visualization tool for students. Don't miss the water wave simulation. It clearly shows the repeating pattern of a periodic wave, helping students understand that the particles oscillate but are not propelled forward by the wave.
Level: Grades 6-12
This is a free video software tool for analyzing the motion captured in short video clips. Its features include position, velocity, and acceleration tracking, multiple reference frames, and model analysis. Students can analyze the motion of objects in a video and overlay simple dynamical models on the video to see how well the model matches the real world. A detailed "help" section is available to users who are newcomers to video analysis software.
References and Collections:
A great resource to augment a module on tsunamis. These are interactive "magazine-style" articles designed to help students understand how tsunamis are generated and why they become so destructive upon reaching shore. Don't miss the excellent animated view of a tsunami caused by subduction zone earthquake.
Level: Grades 9-12
One way to get students excited about wave energy is to study tsunamis. How can a wave that is barely visible to a ship at sea become so destructive upon reaching a shoreline? This set of tutorials, simple enough for students to understand, explains how these catastrophic wave trains originate and propagate through vast oceanic distances. Each tutorial is accompanied by simulations that model the fundamentals of this phenomenon.
Student Tutorials:
This interactive tutorial introduces students to three major types of mechanical waves: transverse, longitudinal, and surface. The text is easy for beginners to understand and is accompanied by animations of wave motion and a self-guided set of questions to assess understanding.
Level: Grades 9-12
Wave Properties: Frequency, Amplitude, Period, Phase (11)
Lesson Plans:
This exemplary unit of instruction was developed by a high school physics teacher to be used with PhET simulations. It includes six complete lesson plans that explore wave properties, the physics of sound, Fourier analysis, and wave phenomena such as reflection and superposition. Most of the lessons require that the simulation be open on a browser while students work. Don't miss the Clicker Questions, which can be readily downloaded for classroom use. Entire unit will take 2-3 weeks, but components may be pulled out separately. NOTE: This resource is available only to PhET registered users, but registration is free and easy.
Level: Grades 9-12
Duration: Multi-Day
Here are two experiments on wave measurement in a ripple tank, appropriate for use in high school physical science or physics classrooms. Students are introduced to using the stroboscope to 'freeze' waves in a ripple tank, and to confirm the relationship between wave speed, frequency and wavelength.
Level: Grades 9-12
This PhET Gold Star winning lesson provides a fun way for middle school students to build a foundation to understand basic wave properties. It guides learners in data collection as they explore amplitude, wavelength, and frequency. Includes lesson plan, pre-lab concept questions, an inquiry-based partner activity (Day 1) and step-by-step student guide for the Day 2 computer modeling activity.
Level: Grades 6-9
Duration: Two Class Periods
Activities:
This PhET favorite has been converted to HTML5 -- all ready for mobile devices and tablets. As the sim opens, you can "wiggle" a string to set up a manual pulse or make waves. Or, choose "Oscillator" and traveling or standing waves will be auto-generated. Students can set amplitude, frequency, damping, and string tension, then observe the results. Finally, students can view the string's vibration with a fixed end, a loose end, or no end. See related teacher-created activity (directly below), developed for use in middle school classrooms with "Wave On a String".
Level: Grades 6-12
Students explore relationships among frequency, amplitude, and wave speed in this inquiry-based activity developed to be used with the PhET simulation Wave on a String (see above). It is appropriate for 9th grade physical science or algebra-based introductory physics. NOTE: This resource is available only to registered users of PhET, but registration is free and easy.
Level: Grades 9-12
Duration: One Class Period
Try using this tutorial as a cooperative learning activity. Students explore the variables that affect wave speed by analyzing sample data and completing a question-and-answer set. It helps build understanding that wave speed is dependent on properties of the medium in which it moves, a central idea to be applied in problems relating to wave energy.
Level: Grades 9-12
This printable student guide/worksheet was created by a middle school teacher specifically for use with the PhET "Wave on a String" simulation (see activity above). Students gather data to explore how frequency, amplitude, wave speed, and string tension are related.
Level: Grades 7-9
Duration: One Class Period
This student worksheet was developed by a high school teacher for use with the PhET simulation "Wave on a String". It provides a very thorough road map for students to learn about amplitude and frequency in an interactive environment. It's appropriate for Grade 9 Physical Science or for Conceptual Physics courses. Allow two days. NOTE: This resource is available only to registered PhET users, but registration is free and easy.
Level: Grades 8-10
Student Tutorials:
Students often confuse the frequency of a wave with its period. This short tutorial, part of The Physics Classroom, promotes understanding of both properties of waves. A question-and-answer set is provided at the end. Team it with the companion tutorial on wave amplitude and energy transport (directly below).
Level: Grades 9-12
The amount of energy carried by a wave is related to its amplitude. This interactive tutorial, part of The Physics Classroom, explores energy transport in a wave and provides explicit instruction in the proportional relationship between energy and amplitude. Team it with the companion tutorial on frequency and wave period (directly above).
Level: Grades 9-12
Assessment:
This is an excellent unit assessment with solutions, developed by a high school teacher to be used with the PhET simulation Wave on a String. It assesses understanding of fundamental wave properties, interference, standing waves, and beginning harmonics. It is formatted so that students can make responses online at the same time they are interacting with the simulation. Allow two class periods. NOTE: This resource is available only to registered PhET users, but registration is free and easy.
Level: Grades 9-12
How Waves Move and Interact: Reflection, Refraction, Interference (11)
Lesson Plans:
Students should whenever possible experiment for themselves using real equipment, rather than viewing only computer representations of ripple phenomena. This educators' guide gives detailed information about how to acquire, set up, and implement ripple tank experiments in the physical science or physics classroom. See related ripple tank activities developed by the same authors (below).
Level: Grades 6-12
Ripple tanks provide a powerful way to help students visualize wave behavior in general. This set of 8 introductory labs allows students to become comfortable with ripple tanks by doing some simple experiments with pulses. Appropriate for grades 6-12, with supervision.
Level: Grades 6-12
Activities:
This activity lets students explore the fundamentals of frequency, amplitude, and damping in a simple wave/string system. Waves can be manually or automatically generated with tension settings from low to high. View the wave as a pulse or as a driven oscillation. Choose a fixed end, loose end, or no end. Values of amplitude and frequency can also be adjusted, giving a great opportunity for bringing in math.
Level: Grades 6-12
Students interactively explore properties of waves as they view simulations of a dripping faucet, an audio speaker, and a laser. By observing wave sources and mediums for water, sound, and light, students can compare the behavior of different types of waves. Choose Light as a medium and add a second source or a pair of slits to create an interference pattern.
Level: Grades 8-12
A set of three classroom demonstrations to be used with PhET simulations Wave on a String, Sound, and Wave Interference. Students explore wave reflection, patterns from interfering waves, and the Doppler Effect. The accompanying concept (clicker) questions may be downloaded in Power Point format and adapted for individual teacher use. NOTE: This resource is accessible only to registered PhET users, but registration is free and easy.
Level: High School
Duration: 30 minutes
When two waves interfere, their amplitudes add. This interactive was developed by a high school teacher to help students visualize exactly what is happening to the amplitude of two waves as they pass through each other. Students set the frequency, amplitude, and phase shift of two waves, then click "Add" to see a graph of the sum. Students may choose either addition or subtraction, sine or cosine.
Level: High School Physics
A nice simulation for exploring the basics of wave reflection and refraction. It shows a single wavefront in slow motion as it reaches a medium with a different refractive index. Students can see how each point of the advancing wavefront is the center of a fresh disturbance and source of a new train of waves. They can adjust the refractive index and angle of incidence of either medium.
Level: Grades 8-12
Content Support For Teachers:
A characteristic shared by all waves is that two or more of them moving simultaneously through the same space will superimpose and produce a combined effect. This tutorial, integrated with multiple interactive simulations, promotes understanding of wave superposition in a highly engaging format. Self-test is included.
Level: High School
When waves meet an obstacle or pass through small openings, they may appear to bend or spread out. This phenomena is called diffraction. We see examples of wave diffraction every day, but what is the physics behind it? This exemplary tutorial offers a multimedia tour of diffraction around objects, diffraction through slits, and various effects of diffraction.
Level: High School
Student Tutorials:
An introduction to wave behavior, created by a high school teacher. We suggest having students start with the section "Parts of a Wave", then proceed to the "Interference" section and watch the animations on constructive and destructive interference. These sections could be viewed using a classroom projector and one internet connection. For a related computer lab activity, see the "Wave Adder" in Activities above.
Level: High School Physics
Assessment:
This is an excellent unit assessment with solutions, developed by a high school teacher to be used with the PhET simulation Wave on a String (see link under "Activities" above). It assesses understanding of fundamental wave properties, interference, standing waves, and beginning harmonics. It is formatted so that students can make responses online at the same time they are interacting with the simulation. **Allow two days if completed in computer lab. NOTE: This resource is accessible only to registered PhET users, but registration is free and easy.
Level: High School Physics
Standing Waves and Resonance (4)
Activities:
This simulation shows the standing wave patterns that are produced on a violin, a string medium that is fixed on both ends. Students can toggle from 1st-5th harmonics to see the standing wave pattern of each. The sum of all the harmonics can also be displayed.
Level: Grades 9-12
References and Collections:
The phenomenon of resonance becomes very important in structural engineering, as can be observed in this historic video of the 1940 collapse of the Tacoma Narrows Bridge. The famous suspension bridge disaster occurred when high wind gusts set up a resonant vibration in the bridge, causing large-amplitude oscillatory motion. This video was digitally reformatted from the original film footage shot on the scene.
Level: K-12
Duration: 5 Minutes
The science of music offers a great springboard to spark student interest in wave interference, standing wave patterns, and harmonics. This unique collection takes students on an exploration of the physics behind woodwinds, brass instruments, string, and more. Don't miss the "Sounds of World English" section: students can map their own speaking accents.
Level: High School
Student Tutorials:
Standing waves are non-traveling vibrations. They are produced when an incident wave and the reflected wave interfere in a way that they appear to be standing still. Standing wave patterns are readily observable, notably in musical instruments. This interactive tutorial gives students a good foundation for understanding why and when this complex phenomenon occurs.
Level: High School Physics
Duration: One Class Period
The Physics of Sound (4)
Lesson Plans:
A set of exemplary modules related to sound and music, developed for use in middle school and high school. It's broken into well-organized short components for teachers who may wish to teach only one element of this subject matter. Included are lessons and activities on frequency, wavelength, amplitude, pitch, the physics of sound, rhythms and beats, standing waves, harmonic series, and tuning systems. Worksheets include answer keys.
Level: Grades 6-12
References and Collections:
Don't miss this collection of more than a dozen videos compiled by a physicist to help high school students understand the physics of sound. Observe a resonating glass break, view and observe jets breaking making a sonic boom, and more.
Level: Grades 6-12
Don't be scared off by the title of this item. It is a fascinating resource that features a "thematic search engine" for locating information and examples of sound, sound waves, acoustics, hearing, and other related topics. Each topic is accompanied by audio clips from the library of the World Soundscape Project. For example, the topic "Hearing Loss" contains an audio simulation of normal and impaired hearing as a result of noise exposure. Students will enjoy playing around with this one.
Level: Grades 6-12
The science of music offers a great springboard to spark student interest in wave interference, standing wave patterns, and harmonics. This unique collection takes students on an exploration of the physics behind woodwinds, brass instruments, string, and more. Don't miss the "Sounds of World English" section, which allows users to map their own speaking accents.
Level: High School