1. Air, It’s Really There

2. Are gases, such as the gases in air, matter? The air around you is made up of some different gases – nitrogen, oxygen, carbon dioxide, water vapor, and very small amounts os osme others. Gases are made of molecules, however the molecules are much farther apart than the molecules in liquids or solids. Since the molecules of a gas have mass and take up space, gas is matter.

3. Air, It’s Really There Demonstrate that air has mass.

4. Air, It’s Really There Complete numbers 1 and 2 on the activity sheet.

5. Air, It’s Really There The molecules of a gas have very little attraction for one another and barely interact with each other. They just collide and bounce off. It may be hard for students to accept, but in the space between the gas molecules there is Molecular Model Animation “Particle of a Gas”. NOTHING.

6. Air, It’s Really There If gas molecules aren’t attracted to each other and can just float around, why don’t they all just float away? Very light gases like hydrogen and helium have floated away and there are vey little of these gases in our atmosphere. Different heavier gases, such as nitrogen, oxygen, water vapor, and carbon dioxide, surround the Earth. Gravity holds these gases near the Earth as our atmosphere.

7. Air, It’s Really There You will now complete the Activity and What Did You Observe portions of the lab sheet. Lab Recap: When the bottle is placed in hot water, a bubble forms at the top of the bottle. When the bottle is placed in cold water, the bubble gas smaller. It may actually be pushed down into the bottle.

8. Air, It’s Really There Molecular Model Animation “Heating and Cooling Gas in a Bottle”. The red arrows in the animation represent the outside air pushing down on the bubble film. Heating the air inside the bottle makes the moluecules move faster. These faster moving molecules hit the inside of the bottle and more frequently.

9. Air, It’s Really There These molecules push against the inside of the bubble film harder than the surrounding air pushes from the outside. This pushes the bubble film up and out, forming a bubble. Cooling the gas makes the molecules move more slowly. These slower-moving molecules hit the inside of the bottle and the bubble film less often and with less force.

10. Air, It’s Really There The molecules in the surrounding air are moving faster and push against the bubble from the outside. Since these outside molecules are pushing harder, the bubble gets pushed down and gets smaller. Complete the Explain It With Atoms & Molecules section of the activity sheet.

11. Air, It’s Really There Molecules of air inside the bottle move faster when they are heated and push harder against the outside air. This makes the bubble form. When the air inside the bottle is cooled, the molecules move slower and do not push as hard against the outside air. The outside air pushes against the bubble, making it go down.

12. Air, It’s Really There Molecular Model Animation “Heating and Cooling Gas in a Bottle”. The molecules shown here are from three different substances all at room-temperature. The solid is a metal, the liquid is water, and the gas is air.

13. Air, It’s Really There Put the following in your notes: Solid Particles are very attracted to one another The particles vibrate but do not move past one another. The atoms or molecules stay in fixed positions because of strong attractions for one another. A solid has a definite volume and definite shape.

14. Air, It’s Really There Put the following in your notes: Liquid Particles are attracted to one another. The particles vibrate but are also able to move past one another. A liquid has a definite volume but does not have a definite shape.

15. Air, It’s Really There Put the following in your notes: Gas Particles are not attracted to each other much at all and move freely. A gas does not have a definite shape or volume. The atoms or molecules of a gas will spread out evenly to fill any container.

16. Air, It’s Really There Draw a model of solids, liquids, and gases on your activity sheet (#8) like below. Make note that each picture has the same number of motion lines, this indicates that the different substances are at the same temperature.

17. Air, It’s Really There Attractions strong enough to keep atoms in orderly arrangement Vibrate in fixed positions Definite volume and shape Attractions keep particles together but they can slide past each other Random arrangement Definite volume, not definite shape Attractions too weak to keep particles together Particles move independently No definite volume or shape

18. Air, It’s Really There After watching the following animation you will complete number 9 on your activity sheet.

19. Air, It’s Really There Contracting and expanding happens differently for a gas than it does of liquids and solids. Cooling When a liquid or solid is cooled, the particles slow allowing the attractions between the particles to pull themselves closer together causing the liquid or solid to contract. When a gas in a flexible container is cooled, its atoms or molecules slow down but the attractions between the particles are so weak that they cannot pull themselves closer together. Instead, the slower-moving molecules hit the inside of the container less frequently and with less force. This results in a lower pressure inside the container than outside. The higher pressure on the outside pushes on the container, making, it contract.

20. Air, It’s Really There Heating When a liquid or solid is heated, the particles it is made of move faster. This increased motion competes with the attractions the particles have for each other causing them to move slightly further apart. When a gas is heated, the particles also move faster but they do not have to compete with significant attractions. The particles hit the inside of the container more frequently and with more force. This results in higher pressure inside the container than outside. The higher pressure on the inside pushes on the bubble, making it expand.