OUTREACH : HANDS-ON WORKSHOPS : Star Lab

Transport your students to a starry night sky! Sit back and observe the rotation and revolution of the Earth and listen to the constellation legends of ancient cultures.

Starlab Requirements

• Maximum capacity of 25-30 students
• Requires a room separate from all other activities
• Minimum ceiling clearance of 12 ft
• Minimum floor space of 25 ft x 25 ft
• Inside location with a grounded outlet

Michigan Curriculum Framework Benchmarks

• generate questions about the world based on observation (SCI.I.1.E.1)
• explore motions of the earth, sun and moon (SCI.V.4.E.2)
• describe observations of the night skies (SCI.V.4.MS.3)
• compare stars to our sun (SCI.V.4.HS.1)

Star Lab Pre-visit Vocabulary

Astronomy: A laser is a focused beam of light.

Constellation: A group of stars in which someone saw a picture.

East: The direction of the rising sun.

Gas: One of the three states of matter, where molecules are spread apart.

Moon: A celestial body that revolves around the earth.

North: The direction of the north magnetic pole.

Planetarium: A device that shows the movement of the stars and planets.

Satellite: A celestial body that orbits a planet; a moon.

Solar System: The sun and all that revolves around it.

South: The direction opposite north.

Star: A ball of gas.

Sun: The star at the center of our solar system.

West: The direction of the setting sun.

Zenith: The point in the sky directly overhead.

Star Lab Post-visit Materials

Post-visit activities provide your students with an opportunity to review workshop-presented concepts and introduce related subjects. Below you will find a classroom extension activity and a list of suggested resources for further exploration. We hope that you enjoyed our Outreach Hands-On Workshop, and we look forward to visiting your students again!

Hands-On Activity: Get Lost, Gravity!

Materials

• Plastic Cup
• String
• Ruler
• Scissors
• Tape
• Modeling clay
• Friend

Procedure

1. Cut the string to be 24 inches long.
2. Tape one end of the string to one side of the mouth of the cup. Tape the other end to the side opposite on the mouth of the cup. (They should be set across from each other).
3. Cut a new piece of string to be 6 inches long.
4. Tie the 6-inch piece of string to the center of the longer length of string.
5. Mold a clay ball approximately ½ inch diameter around the hanging length of the shorter string.
6. Ask your friend to hold your cup up above their heads by pinching the string where the short string is tied to the longer string.
7. Go sit on a chair a few feet away from your friend where you can watch both the cup and the clay ball fall.
8. Predict what will happen to both the ball and the cup as they fall.
9. On your “GO!” have your friend let go of the string.
10. Watch the ball and cup as they fall. Repeat the activity to verify your results.

Discussion

You should have noticed that while the cup and ball were falling, they stayed the same distance apart until the cup hit the floor. This is because both the clay ball and the cup were falling at the same speed. The cup was being pulled down by gravity (the natural force of attraction between any two objects, directly proportional to the masses and indirectly proportional to the distances of the falling objects), but the ball was experiencing a feeling of zero gravity. Falling objects experience an apparent weightlessness because there is next-to-nothing (only a few gas molecules in the environment) pressing against the object.

Astronauts in space can experience apparent weightlessness as they orbit Earth in their spacecraft. In orbit, both an astronaut and the spacecraft are constantly falling around the Earth. When you ride in a roller coaster you may feel zero gravity when the ride goes down very steep hills.

The truth of the matter is that gravity will never be totally absent. The pull of an object on another object is always present – even when the objects are very far apart, like in outer space. The strength of a gravitational pull may appear very weak between you and a banana compared to the strength of the gravity between you and the Earth – but the gravitational pull still exists!

Suggested Resources

Books

Cole, Joanna. The Magic School Bus Lost in the Solar System. Scholastic, Inc. 1992
Evert, Laura. Planets, Moons and Stars (Take-Along Guides). Creative Publishing International. 2003
Heifetz, Milton D. A Walk through the Heavens: A Guide to Stars and Constellations and their Legend. Cambridge UP. 1998
Kerrod, Robin. The Book of Constellations: Discover the Secrets in the Stars. Barrons Educational Series. 2002
Rabe, Trisha. There’s No Place Like Space (Cat in the Hat's Learning Library). Random House. 1999
Rey, H.A. Find the Constellations. Houghton-Mifflin, Co. 1976
Thompson, C.E. Glow-In-The-Dark Constellations: A Field Guide for Young Stargazers. Grosset & Dunlap. 1999
VanCleave, Janice. Janice VanCleave’s Astronomy for Every Kid: 101 Easy Experiments that Really Work. John Wiley & Sons. 1991

Internet

Exploratorium: Museum of Science, Art and Human Perception
Exploratorium Teacher’s Institute — Reflections of a Star: How to Find the Angular Diameter of the Sun
KidsAstronomy
NASA
Starchild