Nine Ex p Will Ma eriments an d ke Mov ement Activities Th at Even M ore Fu n!

FORCE AND MOTION Teaching How and Why Things in Our World Move

A complete set of experiments to guide an exciting science unit all about force and motion. Your young students will adore learning about something they love to do - move!

Created By: Karen Langdon

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Table of Contents Introduction ------------------------------------------------------------------------------------------ 3 “Marbles and Gravity” experiment materials and procedures ------------------------- 4-5 “Marbles and Gravity” design pages --------------------------------------------------------------- 6-7 “3D Objects on a Ramp” experiment materials and procedures --------------------- 8-10 “3D Objects on a Ramp” prediction/observation recording form ----------------------- 11 “Parachutes and Air Resistance” experiment materials and procedures -------- 12-13 “Pinwheels and the Force of Wind” experiment materials and procedures ----- 14-15 “Pinwheels and the Force of Wind” template ------------------------------------------------ 16 “Friction on a Ramp” experiment materials and procedures ------------------------- 17-18 “Friction on a Ramp” prediction/observation recording form --------------------------- 19 “Pushing a Bucket” experiment materials and procedures --------------------------- 20-21 “Mr. Egg Goes For a Ride” experiment materials and procedures ------------------ 22-23 “Mr. Egg” experiment predictions/observations forms ------------------------------- 24-26 “Slingshot Monkey” experiment materials and procedures ----------------------------- 27 “Mousetrap” experiment materials and procedures -------------------------------------- 28 “Mousetrap” Push and Pull Stories ------------------------------------------------------------ 29-32 Science writing paper -------------------------------------------------------------------------------- 33 Image licensing acknowledgements ------------------------------------------------------------- 34 Other products available ---------------------------------------------------------------------------- 35

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Introduction This unit is designed to provide you with everything you need to introduce the basic concepts of force and motion. It focuses largely on push and pull, friction, and gravity, and each activity or experiment makes these difficult to see concepts concrete and understandable. You will find a wide variety of experiments. Some take only five or ten minutes, while some take an hour or more. Each experiment is grounded in teaching and reinforcing the inquiry process, while building an understanding of force and motion. For each experiment you will find a material list, procedures, and any necessary data recording forms. You will also find photos of each step in the process. Please note that it is not necessary to use all of the writing components in this unit. In kindergarten, for some activities, observation and participation should be your focus. The writing forms are available to use at your discretion for differentiation, or to use with older students. As always, meet your students where they are. There is also no definite order in which to do these activities, so plan according to time and preparation. Young learners love nothing more than to move. This amazing unit helps them understand the power of forces and motion!

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Marbles and Gravity This is a great experiment for exploring gravity. Kids understand pretty quickly that whatever goes up must come down, but this experiment lets them really explore and manipulate how gravity works. This experiment has many opportunities for differentiation. In kindergarten, I typically pose the questions and simply let the kids explore. In first grade you could extend this work by having the kids first plan, draw, or write about their ideas and their discoveries.

Materials:

Marble Construction Set

Stopwatch

Design Sheets (included in this packet)

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Procedure: 1. Review the steps in the inquiry process (ask a question, make a prediction, do an experiment, compare outcomes.) 2. Introduce the questions for this experiment: How can we build a structure that works WITH gravity? and How can we build a structure that works AGAINST gravity? 3. Have students design, either individually or in groups, two structures. Have them consider how they can use the marble tubing pieces to slow the marble down, making it take a long time to reach the ground, and how they can make the descent very fast. Have them discuss, draw, and write their ideas using the forms provided. 4. Have students then test out their ideas by building the structures they design. They should build each structure, then use the stopwatch to time how long a marble takes to reach the ground. 5. Have students or groups share their experience, and discuss what force ultimately pulled the marble down. 6. Have students use the “science writing” paper to write about their science experiment experience.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Defying Gravity - Marble Races Design a marble contraption that will “fight” gravity. With this design, the marble will take a long time to reach the ground.

Construction Notes:

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Assisting Gravity - Marble Races Design a marble contraption that will assist gravity. With this design, the marble will take very little time to reach the ground.

Construction Notes:

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

3-D Objects on a Ramp This experiment helps kids to explore gravity, friction, and 3-D solids. This is an excellent way to integrate math and science goals! This experiment teaches about friction, gravity, 3-D solids, measuring, and inquiry process.

Materials:

Ramp With Rails (I use a long block with wrapping paper tubes taped to the sides.)

Blocks, Table, or Chair (You will need something that you can prop the ramp against)

Yard Stick or Tape Measure

Stopwatch

Data Recording Sheets (included in this packet)

3-D Objects (cube, sphere, cylinder, rectangular prism, triangular prism, car)

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Procedure: 1. Review the steps in the inquiry process (ask a question, make a prediction, do an experiment, compare outcomes.) 2. Introduce the questions for this experiment: How does the shape of an object affect the speed with which it will go down a ramp? And How does the shape of an object affect the distance an object will travel from the bottom of a ramp? 3. Have students make predictions on the attached forms. They should rank objects from 1 -6, predicting the speed and distance of the different 3-D objects. 4. As a group, test out each object. Begin by testing the speed of each object’s descent. Have a student release the object from the top of the ramp, and time how long it takes for the object to reach the bottom of the ramp. Repeat with all objects, recording the times as you go. 5. Rank the speed of each object and have students record on the data sheet. (The speed should be nearly the same for every object) 6. As a group, test the distance that each object travels from the bottom of the ramp. Have a student release the object from the top of the ramp, and mark where the object stops moving. Use the yard stick or tape measure to measure the distance from the bottom of the ramp to the stopping place. Repeat with all objects, recording the distances as you go.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

7. Rank the distance of each object and have students record on the data sheet. (The distance should be largely affected by the shape of the object. This is due to the amount of friction each object has against the floor as it moves.) 8.Discuss your findings as a group, ensuring that students understand the role that friction plays. 9. Have students use the “science writing” paper to write about their science experiment experience.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Name ________________________

Speed Rank the objects according to speed. 1=Fastest, 6=Slowest

Prediction: __________

__________

__________

__________

__________

__________

__________

__________

__________

__________

Actual Result: __________

__________

Distance Rank the objects according to speed. 1=Furthest, 6=Shortest

Prediction: __________

__________

__________

__________

__________

__________

__________

__________

__________

__________

Actual Result: __________

__________

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Parachutes and Air Resistance This is a great experiment for exploring gravity, as well as forces that fight gravity. Children can explore how air resistance works to slow the force of gravity. This experiment has many opportunities for differentiation. This is a great experiment to highlight a point quickly and clearly. And the best part, it can be completed in just five minutes!

Materials:

Two Small Figures (Playmobil or Lego figures work well)

4 Pieces String or Yarn (each about 10 inches long)

Plastic Grocery Bag

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Procedure: 1. Review the steps in the inquiry process (ask a question, make a prediction, do an experiment, compare outcomes.) 2. Introduce the question for this experiment: Will a parachute affect how fast a figurine will fall to the ground? 3. Discuss predictions with students. Have them talk with a partner about what they think will happen, and why. 4. As a group, test out each condition. (You can have the parachute pre-made, or you can make it together as a group. To construct the parachute, cut a large square out of the plastic bag. Poke a small hole in each corner of the bag. Tie a piece of string to each hole, and tie the opposite end of the string to the figurine.) To test, stand on a chair. Begin by dropping the figurine that has no parachute. Notice how quickly it falls. (You can count, or just take note.) Then, stand on the chair and drop the figurine with the parachute attached. Be sure to spread the bag out as you drop to ensure the parachute inflates. 5. Discuss what you noticed with the two drops. The figurine with the parachute should have fallen more slowly than the figurine without the parachute. At this point, discuss air resistance, and how air pushes against the parachute to slow the force of gravity. 6. Have students use the “science writing” paper to write about their science experiment experience.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Pinwheels and the Force of Wind This activity helps kids to explore the pushing force that wind can apply. It also helps them to understand that increasing the force of the push increases the reaction (speed of the moving pinwheel.)

Materials:

Pencil

Scissors

Straight Pin

Small Beads

(one per student)

(one pair per student)

(one per student)

(two per student)

Pinwheel Template (one per student)

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Procedure: 1. Discuss wind as a force with the kids. Explain that wind can push or pull, and the force of the wind changes the strength of the push or pull. (This is a great time to talk about wind forces they have observed - wind blowing leaves, wind pushing against an open coat, a tornado, etc) 2. Assemble the pinwheels. First have each student cut along the dotted lines on the attached worksheet. They should cut out the square and cut each diagonal line, stopping at the inner circle. 3. Then help each student fold the tips of the pinwheel towards the center dot. They can check their work by ensuring they are pulling the tips with the black dots toward the center, and hold all four pieces together against the center dot. 4. Take a straight pin and string one bead on to the straight pin. 5.Use the straight pin to poke through all four corners of the pinwheel and finally in to the center hole. This should create the pinwheel “look.” 6. Put the other bead on the back end of the straight pin, so the pinwheel is sandwiched between the beads. (On some pins there will only be room for one bead. If this is the case, eliminate the first bead.) 7.Finally, poke the remaining end of the straight pin into the eraser on the pencil, taking care not to poke the pin all the way through. You have a finished pinwheel! 8.Have students experiment with their pinwheels. Have them change the strength of their breath, blowing soft, and then harder, to observe the differences. Discuss their observations.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Copy on to chosen paper color. Cut out the whole square, and cut along each dotted line, stopping when you reach the center circle.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Friction on a Ramp This experiment helps kids to explore the force of friction. This is a great experiment for making real world connections. You can discuss practical applications of materials with different levels of friction.

Materials:

Ramp (A large wooden block works well for this.)

Canvas (Large enough to cover the surface of the ramp.)

Wooden Blocks (You will need something that you can prop the ramp against)

Rubber Mat (I use drawer liner. It must be large enough to cover the surface of the ramp.)

Stopwatch

Tape

Fabric

White Board

(I use a t-shirt. It must be large enough to cover the surface of the ramp.)

(It must be large enough to cover the surface of the ramp.)

Small Wooden Cube

Data Sheet (One per student included in this packet..)

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Procedure: 1. Review the steps in the inquiry process (ask a question, make a prediction, do an experiment, compare outcomes.) 2. Introduce the questions for this experiment: How does the surface of a ramp affect the amount of friction on the ramp (and the speed with which and object will go down the ramp?) What surface covering is the safest? 3. Have students make predictions on the attached forms. They should rank materials from 1 - 5, predicting the speed of the descent with different surface coverings. 4. As a group, test out each surface. Begin by choosing a surface covering to test, and attaching it to the ramp using the tape. (Note: I recommend testing this out before students are present to ensure that your ramp is at a good angle. If it is too steep, objects will tumble, and the experiment will not work properly, but it needs to be steep enough for the block to slide.) Have a student release the wooden cube from the top of the ramp, and time how long it takes for the cube to reach the bottom of the ramp. Repeat with all surfaces, recording the times as you go. 5. Rank the speed of each surface and have students record on the data sheet. Compare the students’ predictions to the actual results, and discuss their observations. They should discover that some surfaces (wood, white board) have less friction, and objects fall faster, whereas other surfaces have more friction (canvas, rubber) and slow the descent. Discuss this in relation to real world contexts. For example, tires are covered in rubber to increase friction and make driving safer! 6. Have students use the “science writing” paper to write about their science experiment experience.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Name ________________________

Predictions Rank the surfaces according to predicted speed. 1=Fastest, 5=Slowest

Wood __________

Fabric __________

White Board

Canvas

__________

__________

Rubber __________

Actual Results

Speed of Descent on Each Surface: _____ seconds

_____ seconds

_____ seconds

_____ seconds

_____ seconds

Rank the surfaces according to actual speed. 1=Fastest, 5=Slowest

Wood __________

Fabric

White Board

Canvas

Rubber

__________

__________

__________

__________

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Pushing a Bucket - Strength of Force This is a great introductory experiment for exploring push and pull. It is quick, easy, and the kids love it! I recommend doing this experiment as a simple exploration, focusing on observations and discussion, rather than written work.

Materials:

Large Plastic Bin (I use our class recycling bin.)

Something Heavy (I use a couple of piles of classroom books.)

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Procedure: 1. Set up in a space where you have room to run! I have my kids sit along the wall in the hallway. Designate a starting and finish line. 2. Ask for a volunteer. Have the student run as fast as they can, pushing the empty bin from the starting line to the finish line. 3. Place the books or other heavy object in the bin, and have the same student push the bin back. Observe how the speed of the run changes, and how the student must push harder. Ask the student to tell the class about they had to change the amount of force they used to push the heavier bin. 4. Repeat as desired with more students. (I usually do two pairs total.) 5. Ask for a student who is really strong! Choose a student who LOVES to move! Then select another volunteer (a big kid is great for this), and have them sit in the bucket. Have student one push the bin with student two inside from one line to the next, and observe how much force they must use. Repeat as desired. The kids LOVE this! 6. Discuss how more force is needed to move heavier objects.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Mr. Egg Goes For A Ride! This experiment is an excellent choice for a large group experiment. This experiment allows you to teach inquiry process, force and motion, and car safety (seatbelt use).

Materials:

4 Eggs

Car with Egg “Seat”

Ramp With Rails

(This will give you a couple extra. I like to give them faces.)

(You can use any small car that you can attach a cup to.)

(I use a long block with wrapping paper tubes taped to the sides.)

Prediction Chart

Blocks or Tables

(I make a large group chart on poster board. I also included smaller charts and record sheets as options.)

(You will need something that you can raise/lower to support the ramp.)

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Procedure: 1. Review the steps in the inquiry process (ask a question, make a prediction, do an experiment, compare outcomes.) 2. Introduce the question for this experiment: What is the safest way for Mr. Egg to drive? 3. Introduce the varying conditions (low hill with and without a seatbelt, high hill with and without a seatbelt) and the varying outcome possibilities (fine, bruise, crack, and mess). 4. Have students consider one condition and make predictions. Repeat for the other three conditions. You could do this as a large group on a poster chart, or have students write their own predictions. 5. Test out one condition, and record the results. Repeat for the other three conditions. 6. Compare predictions to the actual outcomes. 7. Draw a conclusion about the safest way for Mr. Egg to drive. Discuss any questions or surprise findings. 8. Have students use the “science writing” paper to write about their science experiment experience.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Our Predictions F = Fine B = Bruise (small crack, no egg guts)

Scientist’s Name

Low Hill With a Seatbelt

Low Hill With No Seatbelt

C = Crack (with some egg leaking) M = Mess (smashed egg)

High Hill With a Seatbelt

High Hill With No Seatbelt

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

F = Fine B = Bruise (small crack, no egg guts)

Scientist’s Name

Low Hill With a Seatbelt

C = Crack (with some egg leaking) M = Mess (smashed egg)

Low Hill With No Seatbelt

High Hill With a Seatbelt

High Hill With No Seatbelt

Actual Result Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Scientist Name: Prediction

Actual Result

Prediction

Actual Result

Low Hill With a Seatbelt

Low Hill With No Seatbelt

High Hill With a Seatbelt

High Hill With No Seatbelt

Scientist Name:

Low Hill With a Seatbelt

Low Hill With No Seatbelt

High Hill With a Seatbelt

High Hill With No Seatbelt Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Slingshot Monkey! - Opposite Forces This is a hilarious experiment that teaches a tricky concept - every action has an equal and opposite reaction. The concept is best taught by having students observing the teacher using the slingshot. Start with this, but then, of course, let the kids enjoy trying it out too! I recommend doing this experiment as a simple exploration, focusing on observations and discussion, rather than written work.

Materials: Slingshot Animal (I ordered one on Amazon for a couple of dollars..)

Procedure: 1. Introduce one of the laws of motion to your students - for every action there is an equal and opposite reaction. 2. Demonstrate in front of the group how this works. Show them the slingshot critter, and have them observe several slings. Be sure to point out that the farther back you pull the slingshot, the farther the animal flies (the stronger the initial pulling force, the stronger the reactionary flight.) Repeat as desired, giving students turns if you like.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Mousetrap - Forces at Work This activity is a fun way to see forces at work, and their consequences. With so many pushes and pulls happening in quick succession, your scientists will have lots to observe and discuss! I recommend doing this experiment as a small group exploration. Because of the intricacy of the game, the students will need to be able to see up close!

Materials:

Mousetrap (TM) Game

Mousetrap (TM) Story Forms (included in this packet)

Procedure: 1. BEFORE you begin working with students, assemble the entire mousetrap, and test it to be sure it works. For this activity, you will not actually be playing the mousetrap game. Instead, you will be observing the complete trap. 2. Using a combination of demonstration and student participation, explore the way the trap works. Ask students what they notice, and see if they can identify any forces. Look at each section of the trap individually, and discuss the forces at work. 3.Work with the Mousetrap story forms (included in this packet). Either read the story to the students, demonstrating as you go, or ask students to independently fill in the forms that have blanks, thinking about the forces at work. Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

A Story About A Mouse Trap In each blank, write in either:

pushes

or

pulls

A person turns a crank. The crank ________________ a rubber band.

The rubber band ________________ a stop sign.

The stop sign ________________ a green boot.

The green boot ________________ a bucket.

The bucket tips, and gravity _____________ the ball down a ramp.

Gravity __________ the ball down another ramp. Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

The ball ______________ the blue post.

The blue post _______________ the red shelf.

Gravity _________ the ball through two holes.

The ball ______________ the teeter totter.

The teeter totter ____________ the man.

Gravity __________ the man into the tub.

The tub _______________ the yellow post.

Gravity ___________ the basket down the yellow post! Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

A Story About A Mouse Trap A person turns a crank.

The crank pulls a rubber band.

The rubber band pushes a stop sign.

The stop sign pushes a green boot.

The green boot pushes a bucket.

The bucket tips, and gravity pulls the ball down a ramp.

Gravity pulls the ball down another ramp.

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

The ball pushes the blue post.

The blue post pushes the red shelf.

Gravity pulls the ball through two holes.

The ball pushes the teeter totter.

The teeter totter pushes the man.

Gravity pulls the man into the tub.

The tub pushes the yellow post.

Gravity pulls the basket down the yellow post!

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Scientist Name:

Experiment Name:

In this experiment I learned/noticed/observed:

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.

Licensing Acknowledgements The images used in this work were either my own photographs, or are acknowledged below. They are free to use via the creative commons for commercial use licensing. play mobil figure - http://www.flickr.com/photos/25321693@N00/50548903 yarn - http://www.flickr.com/photos/96466040@N00/445404842 plastic bag - http://www.flickr.com/photos/43264265@N00/2152704346 pencil - http://www.flickr.com/photos/40944554@N04/6810399874 scissors - http://www.flickr.com/photos/24363893@N00/2500283558 pins - http://www.flickr.com/photos/53326337@N00/4261870141 beads - http://www.flickr.com/photos/54331051@N05/5932156999 fabric - http://www.flickr.com/photos/35237092493@N01/2380799143 rubber mat - http://www.flickr.com/photos/47429460@N00/5574749987 white board - http://www.flickr.com/photos/7852439@N07/2886338586 canvas - http://www.flickr.com/photos/60364452@N00/2100724010 tape - http://www.flickr.com/photos/26170836@N05/5649020434 pile of books - http://www.flickr.com/photos/57280691@N02/5843032561 low hill - http://www.flickr.com/photos/93849157@N00/2278051662 steep hill - http://www.flickr.com/photos/26978304@N08/5157543554 seat belt - http://www.flickr.com/photos/86745603@N00/5167426715

Copyright © 2012 Karen Langdon All rights reserved by author. Permission to copy for classroom use only. Electronic distribution limited to classroom use only.