2. It’s another WEINERPOINT PRESENTATION

3. PART III

4. Polar Bonds

5. We know a COVALENT bond comes from sharing the bonding pair of electrons

6. FF Shared pair (bonding pair)

7. FF The nucleus of each atom pulls on the bonding pair.

8. FF Both atoms have equal pull, so the bonding pair is shared equally.

9. HCl If two different atoms share a bond, one will pull more strongly on the bonding electrons.

10. HCl

11. H

12. H

13. H

14. H

15. H

16. H

17. H

18. H The bonding electrons carry negative charge.

19. HCl The closer they get to the chlorine atom, the more negative it gets. The farther they get from the hydrogen, the more positive it gets.

20. HCl + _ But the charge is only partial. Hydrogen has not lost the electrons as in the formation of an ion.

21. HCl There is an unequal sharing of electrons.

22. HCl The partial charge is denoted by a + or – and the Greek letter delta,   –  +

23. The partial charge is denoted by a + or – and the Greek letter delta,   –  +

24.  –  +

25. A polar bond is a bond in which the bonding electron pair is shared unequally. A polar molecule is a molecule with regions of partial negative (  –) and partial positive (  +) charge.

26. The degree of sharing (equal to unequal) is determined by the electronegativity difference between the two atoms.

28. Two atoms of equal electronegativity will share the bond equally FF

29. HCl Two atoms with a small difference in electronegativity will share unequally, resulting in partial charge. 3.0 2.1

30. HCl Two atoms with a small difference in electronegativity will share unequally, resulting in partial charge.  –  +

31. HCl This is a polar bond: The bonding pair is, on average, closer to one atom.  –  +

32. HCl  –  +

33. FK Two atoms with a large difference in electronegativity will result in a loss of an electron, resulting in a full charge. 4.0 0.8

34. FK

35. FK

36. FK

37. FK

38. FK

39. FK

40. + _ FK positive ionnegative ion

41. A polar bond in a molecule may make the entire molecule polar, with one end slightly positive and the other end slightly negative.

42. Hydrogen chloride is an example of a polar molecule. HCl  –  +

43. The SHAPE of the molecule determines whether its polar bonds make the molecule polar

44. In CF 4 the fluorines are symmetrically arranged around the carbon.

45. The fluorines all pull on the valence electrons in opposite directions, effectively cancelling out the polarity of the bonds

46. CF 4 has four polar bonds but it is a non-polar molecule: There is no partial charge on the molecule.

47. The two hydrogens of water are not symmetrically positioned around the oxygen.

48. The O-H polarities do not cancel, and the molecule carries a partial charge.  –  +

49. Water is a liquid instead of a gas because the partial positives and negatives attract each other.  +  –  +  –

50. This attraction holds the molecules together, forming a liquid rather than the spread out molecules of a gas.  +  –  +  –