Chapter 4 – States of Matter Presentations

Due Monday 12/19

You are learning about the states of matter.  It is your group’s job to master your content area.  You will read various books about your section in the textbook and research your content on the internet. 

Focus points: movement/motion of molecules, examples in our daily lives, how they affect us.

Each group will make:

1.  A visual presentation of their material: make a slideshow/PowerPoint and/or a display board; use physical examples such as a demonstration, a mini-lab, etc. (The physical examples can be done at home; just take pictures and add them to your presentation.)

2. A written summary of their subject matter; one page typed (~250 words, max. 300).  Each group member will attach their contribution to the final paper. I will collect each person's rough draft AND the final paper.  
Your paper should consist of the following: summary of your presentation, how this affects us in life, real world examples, molecular motion, how this is related to what we have already learned in class, i.e. energy

3. Three test questions about their material

Each person must contribute to their presentations; failure to do so will result in the group losing a letter grade.

Group 1 – Solids

Group 2 – Liquids

Group 3 – Gases

Group 4 – Solids ßàLiquids (melting/freezing)

Group 5 – Liquids ßà Gasses (evaporation/condensation)

Group 6 – What is Matter? States of Matter Graph

Group 7 – Density

Group 8 – Heat, Temperature, and Thermometers

http://www.neok12.com/States-of-Matter.htm

http://www.chem4kids.com/files/matter_intro.html

http://www.strangematterexhibit.com/index.html

http://www.nyu.edu/pages/mathmol/textbook/4gradecover.html

http://www.bbc.co.uk/schools/scienceclips/ages/9_10/gases.shtml

http://www.chem4kids.com/files/matter_changes.html

http://www.harcourtschool.com/activity/states_of_matter/index.html

http://idahoptv.org/dialogue4kids/season7/matter/facts.cfm

Chapter 4 - States of Matter

Chapter 4 - States of Matter

Phase Change diagram   

 

The motion of particles helps to explain the phases (states) of matter.   

molecules of solid            molecules of liquid                     molecules of gas

States of Matter

Matter is anything that has mass and takes up space.  Our food, drinks, homes, pens, and even our bodies are made up of matter.  There are three states or phases of matter that are important to us: solids, liquids, and gases.

Solid water = ice             Liquid water = fluid water   Gaseous water = water vapor

Solids

1.    Solids can turn into liquids.

2.   Solids have a definite shape.

3.   Solids have a definite volume.

Liquids

1.   Liquids have a definite volume.

2.   Liquids do not have a definite shape; they take the shape of their container.

3.   Liquids can turn into either a solid or liquids can turn into a gas.

Gases

1.   Gases can turn into liquids.

2.   Gases do not have a definite shape.

3.   Gases do not have a definite volume.

4.   Most gases are invisible.

http://www.neok12.com/States-of-Matter.htm

http://www.chem4kids.com/files/matter_intro.html

http://www.strangematterexhibit.com/index.html

http://www.nyu.edu/pages/mathmol/textbook/4gradecover.html

http://www.bbc.co.uk/schools/scienceclips/ages/9_10/gases.shtml

http://www.chem4kids.com/files/matter_changes.html

http://www.harcourtschool.com/activity/states_of_matter/index.html

http://idahoptv.org/dialogue4kids/season7/matter/facts.cfm

 http://videos.howstuffworks.com/discovery/29388-assignment-discovery-states-of-matter-video.htm

•Text Ch. 4 Review

•- p. 129 Visualizing Main Ideas

•- pp. 130-131 #1,2,4,6,10,11,13,14,15,21,22,25

LAB #8 – Simple Machines Help Us

LAB #8 – Simple Machines Help Us

A simple machine is a machine with few or no moving parts. Simple machines make work easier.  They can change the magnitude of force, the direction of the force, or the distance that the force travels.  Some examples of simple machines are: Screw, Wheel and Axle, Wedge, Pulley, Inclined Plane, and Lever. 

Problem      

 How do simple machines help us?

Hypothesis

Materials

 Various simple and compound machines

Procedure

You will be making observations on various objects that your teacher passes out and on objects located in the classroom.  You must fill out the Results section with information about the objects.  If they are simple machines, then you are to infer what kind of simple machines they are; if they are compound machines, then you are to infer what kind of simple machines they are made out of.

Results:

Name of the object	Purpose of the object	What kind of simple machine is it?	Draw a picture of the object
1. Plastic drink top
2. chemistry tongs
3. cooking thermometer
4. scissors
5. light bulb and clamp
6. plastic car
7. spray bottle
8. staples
9. clip on clipboard
10. plastic spoon
11. plastic fork
12. plastic knife
13. nails (on wall)
14. screw (in wall)
15. ramp
16. stapler
17. triple beam balance
18. crazy coaster track
19. blinds
20. wheel on push cart
21. file cabinet drawer
22.
23.
24.
25.

Analysis:

1.       How do simple machines make our lives easier?

               

2.       Pick five objects from the lab and explain how it would be like without them.  How would you accomplish the tasks they help us with without them?

                

3.       Find five simple machines at home and add them to your Results.

Conclusion:

(Write a summary of your experiment.  Was your hypothesis right?  What did you learn?  What could you do next time?  Was it fun?  How is this related to what we are learning in class?)

Lab #6 – Calculating Work pt. 1

Lab #6 – Calculating Work pt. 1

Work = Force x distance

Work = (Force)(distance)

W = Fd

Problem

How is the force needed to lift an object and the distance that object travels related to the amount of work done on the object?

Hypothesis

Materials

Ruler

Chair

Ramp

Object

Object with added mass

Spring scale

Triple Beam Balance

Procedure A

1.         Measure the distance in cm from the floor to the chair’s seat.  Record your data in the Distance column of your Results.

2.         Attach the wood block to the spring scale and pull it the distance from the floor to the chair’s seat.  Record the force that the wood block pulled on the spring scale into your Force column.

3.         Repeat this experiment with the Weight (300 g) and record your data.

4.         Use the work formula to calculate the amount of Joules for the object and the object with added mass and place into the appropriate column.

Results A

Work done without ramp

Object	Force (Newtons)	Distance (cm)	Work (Joules)
Object	________ N	_____cm	_______J
Object with added mass

Independent Variable = ___________________

Dependent Variable = ___________________

Constants = _____________________________________

Procedure B

1. Use your ramp to make an inclined plane from the floor to the chair’s seat and measure the length of the ramp; record this into the Distance column of your Results.
2. Attach the wood block to the spring scale, and pull it from the floor to the chair ’s seat up the ramp.  Record the force that the wood block pulled on the spring scale into your Force column.
3. Repeat this experiment with the Weight (300 g) and record your data.
4. Use the work formula to calculate the amount of Joules for the wood block and the weight (300 g) and place into the appropriate column.

Results B

Work done with ramp

Object	Force (Newtons)	Distance (cm)	Work (Joules)
Object
Object with added mass

Independent Variable = ___________________

Dependent Variable = ___________________

Constants = _____________________________________

ANALYSIS

1.          How did the weight (force) affect the amount of work done on the object?

2.          How did the distance affect the amount of work done on the object?

3.          Compare/Contrast the work done between using the ramp and not using the ramp.

4.          In which trial was the most work done?  In which trial was the least work done?  Explain.

5.          Compare the Force (Newtons) from your “object” in Procedure A with your “object” in Procedure B.  Which was easier? i.e. less force used to pull up

6.          Compare the Force (Newtons) from your “object with added mass” in Procedure A with your “object with added mass” in Procedure B.  Which was easier? 

7.          In these comparisons, what are your independent and dependent variables, and your constants?

Conclusion

(Write a summary of your experiment.  Was your hypothesis right?  What did you learn?  What could you do next time?  Was it fun?  How is this related to what we are learning in class?)