1. Chapter 15 Heat & States of Matter

3. At room temperature most elements are solids. The gases are hydrogen, nitrogen, oxygen, fluorine, chlorine and the noble gases. There are two liquids: bromine and mercury.

5. The state of matter is determined by two factors.

6. 1. Attractive forces between the particles of the material. Liquid Solid Gas

7. 2. Temperature (Average Kinetic Energy)

8. At room temperature which factor determines the state of an element?

9. Transitions between the states of matter We can change the state of matter that a substance exhibits by adding/removing heat.

10. Heat Heat is thermal energy that flows from something warmer to something cooler.

11. Transitions between the states of matter

12. How many states of matter exist? 5

13. Plasma: The fourth state of matter

14. Transitions between the states of matter If we heat a gas to a high enough temperature it becomes a plasma.

15. Plasma A plasma is a super heated ionized gas. –Normally requires extremely high temperatures to form. –It consists of electrons and positively charged gas particles.

16. Plasma Plasmas are the most common state of matter in the universe. It is estimated that 99% of the visible universe is plasma.

17. Plasma Plasmas do not occur as frequently on earth.

18. “Cold” Plasmas

19. Plasmas can exist at much lower temperatures than normal in a vacuum.

20. The Fifth State of Matter Bose – Einstein Condensate (BEC)

21. Bose – Einstein Condensate In the 1920s, Satyendra Bose and Albert Einstein, predicted this new state of matter. However they didn't have the equipment and facilities to make it.

22. Bose – Einstein Condensate In 1995, three scientists, Karl Weiman, Wolfgang Ketterle and Eric Cornell finally created this new state of matter. They were awarded the Nobel Prize in 2001.

23. Bose – Einstein Condensate If plasmas are super hot and super excited atoms, the atoms in a Bose-Einstein condensate (BEC) are total opposites. They are super-unexcited and super- cold atoms.

24. The Fifth State of Matter The BEC happens at super low temperatures. At zero Kelvin all molecular motion stops. At only a few billionths of a degree above absolute zero, you can create a BEC with a few special elements. Cornell and Weiman did it with Rubidium.

25. Time for a Chemistry Joke

28. Bose – Einstein Condensate As temperatures get to within a few billionths of a degree of absolute zero atoms begin to “clump”. The result of this clumping is the BEC. A group of atoms takes up the same place, creating a "super atom." There are no longer thousands of separate atoms. They all take on the same qualities (quantum state) and for our purposes become one “superatom”.

29. What does a Bose Einstein Condensate Look Like? It looks like a dense little lump in the bottom of the magnetic trap/bowl. Picture a drop of water condensing out of damp air. When it first forms, though, the condensate is still surrounded by the normal gas atoms, so it looks a bit like a pit inside a cherry.

30. When matter gets cold enough a dense blob forms in the center. You can see this in the pictures of Cornell and Wieman’s actual data as they cool the atoms from 400 billionths of a degree above absolute zero down to 50 billionths. Bose-Einstein Condensation at 400, 200, and 50 nano-Kelvins

31. States of Matter Video (Video Worksheet) Homework Chapter 15 Worksheet