1 / 16

Calculating energy changes with phase changes

Calculating energy changes with phase changes. SC6 Students will understand the effects motion of atoms and molecules in chemical and physical processes. a. Compare and contrast atomic/molecular motion in solids, liquids, gases, and plasmas.

vevina
Download Presentation

Calculating energy changes with phase changes

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Calculating energy changes with phase changes

  2. SC6 Students will understand the effects motion of atoms and molecules in chemical and physical processes. • a. Compare and contrast atomic/molecular motion in solids, liquids, gases, and plasmas. • b. Collect data and calculate the amount of heat given off or taken in by chemical or physical processes. • c. Analyzing (both conceptually and quantitatively) flow of energy during change of state (phase). GA standards

  3. Why didn’t the temperature of the water in your beaker go above the boiling point (100 C) even though you kept heating it? All the energy was being used to evaporate the water Going from liquid to gas takes energy. What’s happening at the molecular level? Water molecules are attracted to each other. It takes energy to separate them (liquid to gas) Hmmmmmm?

  4. Solid: • lowest energy. • molecules are in fixed place • Liquid • Middle energy • Molecules rolling around each other • Gas • Highest energy • Molecules move independently in straight paths, randomly bumping into each other Solid – liquid – gas at molecular level

  5. Once all the water is gone, the temperature of the steam can be increased if you keep heating it. gas liquid to gas liquid Liquid to gas (cont’d) Temperature Energy

  6. The energy it takes to change 1 g of a substance from liquid to gas is called the heat of vaporization Hv • Hv water = 539.4 cal/g • How much energy will it take to evaporate 15g of water? • Q = Hvm • Q = 539.4 cal/g x 15g • Q = 8091 cal Liquid to gas (cont’d)

  7. What about melting an ice cube? Same holds true. It takes energy to separate the water molecules and get them moving around each other. While the ice is melting, the temperature holds steady at 0 C. Once the ice is all melted, the liquid can be heated. Solid to liquid

  8. Once all the water is gone, the temperature of the steam can be increased if you keep heating it. liquid solid to liquid solid (ice) Temperature Energy

  9. Hf is the energy it takes to melt 1 g of a substance • If the substance is freezing, Hf is negative • Hf water = 333.0 J/g • How much energy does it take to melt 15 g of ice? • Q = Hf m • Q = 330.0 J/g x 15g • Q = 4950 = 5.0 x 103 J Calculating melting energy

  10. Heating curve of water

  11. Cooling Curve of Water

  12. How many joules of heat are given off when 5.0 g of water cools from 75oCto 25oc? (Specific heat of water = 4.184 J/goC)

  13. How many calories are given off when 85 g of steam condense to liquid water? (Hv= 539.4 cal/g)

  14. How many joules does it take to melt 35g of ice at 0oC? (Hf = 333 J/g)

  15. How many joules are required to convert 10.0g of ice at -10.0oC to steam at 150. oC? • Given: Specific heat of • Specific heat of water = 4.184 J/g C° • Specific heat of Steam = 2.03 J/g C° • Specific heat of ice = 2.06 J/g C° • Hv water = 539.4 cal/g • Hf water = 333.0 J/g • 5 part calculation

  16. Page 497 Practice Problem 14.2 Page 497 Section 14.1 Review 4-7 Page 503 Section 14.2 Review 1 Your assignment

More Related