Lab #2: The Spheres Rolling Down the Ramp Into the Plastic Truncated Cone (2023/2024)

You will make a model to help you determine how the mass of an object, like a car or truck, would affect its impact if it crashed. You will roll three balls with different masses down ramps of identical heights and measure how far the cup at the bottom of the ramp gets pushed when the impact occurs. If the cup goes farther, there is a greater impact. 

Initial Predictions, Observations, Inferences:

Predictions
Observations
Inferences

Materials:

• ramp placemat with ruler in cm
• plastic cup with “door” cut out
• ruler (cm)
• 1 text book
• 3 sphere with different masses: ping pong ball, red rubber ball, golf ball
• scale (grams)

Problem: How does mass of an object affect its ability to exert a force on another object?

How does the variable that I'm changing affect the variable that I'm measuring?

Hypothesis:

If I change ______________________,

then the cup will __________________;

and this is my reasoning ______________________.

If I change this variable (Independent Variable),

then the cup will be affected in this way (Dependent Variable),

and I think this because.....

              

Procedure:

1. 1. Set up your ramp and cup as shown in the image at the top. Start by putting one book under the ruler.
2. 2. Measure the height of the book, and record this in your data table; starting height will remain constant. 
3. 3. Hold the ball at the top of the ramp.  Let go of the ball and let it roll down the ramp to hit the cup.  Measure how far the cup moved because of the impact. Record this measurement in your data table.
4. 4. Roll the ball down the ramp three times for each condition. Each of these rolls is a “trial.” Average the measurements you recorded for the three trials in each condition.

Data Table 1: Distance (cm) the ping pong ball pushes the plastic cup

	Trial 1	Trial 2	Trial 3	Average
Ping Pong Ball
Mass of ball =  _____ grams	height = ___cm

Data Table 2: Distance (cm) the red rubber ball pushes the plastic cup

	Trial 1	Trial 2	Trial 3	Average
Red Rubber Ball
Mass of ball =  _____ grams	height = ___cm

Data Table 3: Distance (cm) the golf ball pushes the plastic cup

	Trial 1	Trial 2	Trial 3	Average
Golf Ball
Mass of ball =  _____ grams	height = ___cm

Variables:

Independent
Dependent
Constants

Analysis

• 
  

1. Where did the cup travel the farthest?  What property about that variable causes the difference?

______________________________________________________________________________________________________

2. What is the relationship between the mass of the ball and the distance the cup moved?

___________________________________________________________________________

3. What happens to the velocity of the ball as it rolls down the ramp?

________________________________________________________________________________________________________

4. What is the importance of only changing ONE variable, while keeping the other variables CONSTANT?

___________________________________________________________________________________________________________

5. a. Which Data Table had the greatest Potential Energy? Why?

b. Which Data Table had the greatest Kinetic Energy? Prove this with evidence from your data.

______________________________________________________________________________________________________________

6. If the height of the ramp increases, the amount of potential energy the marble has: increases / decreases (choose one)

7. If the mass of the ball decreases, the amount of potential energy the ball has: increases / decreases (choose one)

8. Set up a mini-investigation to prove that your hypothesis is valid; use data!

- Restate a final Hypothesis: If.... Then...... Reasoning......._______________________________________.

- Take a marble, measure its mass and record it in grams. How do you think the force it exerts on a cup compares to the other spheres? Make a prediction and test it! Review your bar graph and data tables for your reasoning.

9. Friction Mini-Investigation

- Set up your materials like before, but use a fuzzy blue cloth instead of the slick plastic mat for the cup to move across. Use the sphere of your choice; run three trials. Compare this data to the plastic mat data with the same ball. Which situation had the greater frictional force and why? What is your evidence? Use the following information in your explanation, and choose the situation that exhibited the greatest evidence of friction:

The plastic mat exerts a force, friction, that is opposite to the ball and cup's motion; this is why it eventually stops.

The blue cloth exerts a force, friction, that is opposite to the ball and cup's motion; this is why it eventually stops.

____________________________________________________________________________________________________________

 Construct a bar graph showing your results.  Use the following information to assist you with the graph: 

Title - Bar graph showing how mass of a sphere (g) affects the force it exerts on a cup

x-axis - Mass of objects (g) Independent Variable

y-axis - Distance the cup moved (cm) Dependent Variable

*Use a pencil and a ruler when constructing your bar graph*

Use this website to assist you with the graph! --->   https://nces.ed.gov/nceskids/createagraph/

LAB #4 – Heating Earth’s Surface

LAB #4 – Heating Earth’s Surface

copy the title

Sometimes, a plunge in a pool or lake on a hot summer day feels cool and refreshing.  Why does the beach sand get so hot when the water remains cool?  A few hours later, the water feels warmer than the land does.

Problem

What is the effect of radiant energy from a light bulb on the temperature of a tray filled with "soil/land" and a tray filled with "water/sea"?
              ↑                  

Copy the problem, make a hypothesis, use the writing prompts to guide you.

                                                   ↓

Hypothesis

If we add radiant energy from a light bulb to trays filled with "land" and "sea"....

then the temperatures of the trays will ______________________,
and this is because _______________________________________. 

(What will happen to the temperature of the soil and water when the light is turned on?  What will happen to the soil and water after the light has been turned off? Will they cool down evenly?  Will they heat up the exact same?  Will they heat up differently?  Will there be a change in temperature?  Why do I think this?)

Materials         copy the materials

Soil
Water
Containers for soil and water 
Overhead light 
Thermometers 

Stopwatch

Procedure 

DO NOT COPY..  You don't DO this, I did it, watch the videos. 

1.             Add 300 ml of water to one of the boxes and 300 ml of soil to the other box.

2.             Use a thermometer to find the temperature of the water and soil in each container. Record your data in the Results section.

3.             Place the containers side by side underneath the overhead light. Be sure both containers receive the same amount of light.

4.             Measure the temperature of the water in each container at 1-minute intervals for 10 minutes. Record your data in the Results.

5.             After you record your 10 minute reading, turn off the light and take your initial reading with the light off.

6.             Measure the temperature of the water and soil in each container at 1-minute intervals for 10 minutes. Record your data in the Results.

                                         

Results   watch the videos, copy the data into these tables

	Temperature With Light On (°F)	Temperature With Light On (°F)		Temperature With Light Off (°F)	Temperature With Light Off (°F)
Time (min)	Soil	Water	Time (min)	Soil	Water
0			0
1			1
2			2
3			3
4			4
5			5
6			6
7			7
8			8
9			9
10			10

Analysis          Answer these completely, make line graphs

1.         Graph the data from the table using a line graph in degrees Celsius. Use one colored pencil to show data for the water container and a different one to show data for the soil container with the light on.  Make a second graph with the light off. X-Axis: Time (min.), and Y-Axis: Temperature (°C). Draw lines to connect the temperature for each container.

2.         Calculate the total change in temperature for each material.  Do this by using the following formula: 

Total Change = Final Temperature - Initial Temperature

3.         Which material had the greater increase in temperature?  Why do you think this is?

4.         Infer from your graphs which cooled faster—the water or the soil.  How could you prove this?

5. What was your independent variable?  What was your dependent variable?  What are three variables that should remain constant?

6. Relate: What is this modeling in the real world? (Hint: watch above videos)

https://www.wnct.com/news/sunday-science-tidbit-sea-breeze-and-land-breeze/

7a. Draw a picture of the lab setup with the light on.  Label the following: lithosphere (land), hydrosphere (water), sun (light), convection arrow/heating up, convection arrow/cooling down, sea breeze.
7b. Draw a picture of the lab setup with the light off.  Label the following: lithosphere (land), hydrosphere (water), convection arrow/heating up, convection arrow/cooling down, land breeze.