2. Chapter 17-1b 1

3. When a balloon and your hair are charged by rubbing, only the rubbed areas become charged. 2

4. In contrast, when materials such as copper, aluminum, and silver are charged in some small region, the charge readily distributes itself over the entire surface of the material. 3

5. Therefore, it is convenient to classify substances in terms of their ability to transfer electric charge. 4

6. Materials in which electric charges move freely are called conductors. Most metals are conductors. Examples: copper, aluminum, silver 5

7. Materials in which electric charges do not move freely are called insulators. Examples: Glass, rubber, silk, plastic 6

8. Semi-conductors are a third class of materials characterized by electrical properties that are between conductors and insulators. In their pure state, semi-conductors are insulators. 7

9. But the carefully controlled addition of specific atoms as impurities can dramatically increase a semi-conductor’s ability to conduct electric charge. 8

10. Semi-conductors are used in a variety of electronic devices – silicon & germanium. 9

11. Certain materials belong to a fourth class of materials called superconductors. Superconductors become perfect conductors when they are at or below a certain temperature. 10

12. In the example of a balloon and hair becoming charged because they rubbed together, this process is known as “charging by contact”. Insulators are usually charged by contact. 11

13. Another example of charging by contact is a common experiment in which a glass rod is rubbed with silk or a rubber rod is rubbed with wool or fur. The 2 rods become oppositely charged and attracted to one another. 12

14. If you try a similar experiment with a copper rod, the rod does not attract or repel another rod. 13

15. However, if you hold the copper rod with an insulator and then rub it with wool or fur, the rod attracts a charged glass rod and repels a charged rubber rod. 14

16. In the first case, the electric charged produced by rubbing readily move from copper through your body and finally to Earth because copper is a conductor. 15

17. So the copper rod does become charged but soon becomes neutral again. 16

18. In the second case, the insulating handle prevents the flow of charge to Earth and the copper rod remains charged. Both insulators and conductors can become charged by contact. 17

19. When a conductor is connected to Earth by means of conducting wire or copper pipe, the conductor is said to be grounded. 18

20. The Earth can be considered an infinite reservoir for electrons because it can accept or supply an unlimited number of electrons. 19

21. Let’s consider a negatively charged rubber rod brought near a neutral conducting sphere that is insulated so that there is no conducting path to the ground. 20

22. The repulsive force between the electrons in the rod and those in the sphere causes a redistribution of negative charge on the sphere. 21

23. As a result, the region of the sphere nearest the negatively charged rod has an excess of positive charge. 22

24. If a grounded conducting wire is then connected to the sphere, some of the electrons leave the sphere and travel to the Earth. 23

25. If the wire to ground is then removed while the negatively charged rod is held in place, the conducting sphere is left with an excess of induced positive charges. 24

26. Finally, when the rubber rod is removed from the vicinity of the sphere, the induced positive charge remains on the ungrounded sphere. 25

27. The motion of negative charges on the sphere causes the positive charge to become uniformly distributed over the outside. This process is known as induction and the charge is said to be induced on the sphere. 26

28. The charging of an object by induction requires no contact with the object inducing the charge but does require contact with a third object, which serves as a source or sink of electrons. 27

29. A process very similar to charging by induction in conductors takes place in insulators. In most neutral atoms or molecules, the center of positive charge coincides with the center of negative charge. 28

30. In the presence of a charged object, these centers may shift slightly, resulting in a more positive charge on one side of the molecule than the other side. This is known as polarization. 29

31. This realignment of charge within individual molecules produces an induced charge on the surface of the insulator. 30

32. When an object becomes polarized, it has no net charge but is still able to attract or repel objects due to this realignment of charge. 31

33. As with induction, in polarization, one object induces a charge on a surface of another without physical contact. 32