1. Section 9.1

2. The Covalent Bond
Standard: 2a,2b, 2e, 7b Article: Mastering Concepts: 272 (72-76) Terms: Practice Problems: 244 (1-5)
Using a Venn diagram show the difference between ionic, covalent and metallic (3 stars)
Homework:
Cornell Notes: 9.1
Section Assessment: 247(6-11)
Mastering Problems: 272 (88-92) Stamps

3. Apply the octet rule to atoms that form covalent bonds.
Describe the formation of single, double, and triple covalent bonds.
Contrast sigma and pi bonds.
Relate the strength of a covalent bond to its bond length and bond dissociation energy.
chemical bond: the force that holds two atoms together

4. Section 9-1 covalent bond molecule Lewis structure sigma bond pi bond
Section 9.1 The Covalent Bond (cont.)
Section 9-1
covalent bond
molecule
Lewis structure
sigma bond
pi bond
endothermic reaction
exothermic reaction
Atoms gain stability when they share electrons and form covalent bonds.

5. Section 9-1
Why do atoms bond?
Atoms gain stability when they share electrons and form covalent bonds.
Lower energy states make an atom more stable.
Gaining or losing electrons makes atoms more stable by forming ions with noble-gas electron configurations.
Sharing valence electrons with other atoms also results in noble-gas electron configurations.

6. Section 9-1 Atoms in non-ionic compounds share electrons.
Why do atoms bond? (cont.)
Section 9-1
Atoms in non-ionic compounds share electrons.
The chemical bond that results from sharing electrons is a covalent bond.
A molecule is formed when two or more atoms bond.

7. Section 9-1
Why do atoms bond? (cont.)
Diatomic molecules (H2, F2 for example) exist because two-atom molecules are more stable than single atoms.

8. Section 9-1 Why do atoms bond? (cont.)
The most stable arrangement of atoms exists at the point of maximum net attraction, where the atoms bond covalently and form a molecule.

9. Single Covalent Bonds
Section 9-1
When only one pair of electrons is shared, the result is a single covalent bond.
The figure shows two hydrogen atoms forming a hydrogen molecule with a single covalent bond, resulting in an electron configuration like helium.

28. IB 26

29. IB 27

31. Section 9-1
Single Covalent Bonds (cont.)
In a Lewis structure dots or a line are used to symbolize a single covalent bond.
The halogens—the group 17 elements—have 7 valence electrons and form single covalent bonds with atoms of other non-metals.

32. Section 9-1
Single Covalent Bonds (cont.)
Atoms in group 16 can share two electrons and form two covalent bonds.
Water is formed from one oxygen with two hydrogen atoms covalently bonded to it .

33. Section 9-1
Single Covalent Bonds (cont.)

34. Section 9-1
Single Covalent Bonds (cont.)
Atoms in group 15 form three single covalent bonds, such as in ammonia.

35. Section 9-1
Single Covalent Bonds (cont.)
Atoms of group 14 elements form four single covalent bonds, such as in methane.

36. Section 9-1 Sigma bonds are single covalent bonds.
Single Covalent Bonds (cont.)
Sigma bonds are single covalent bonds.
Sigma bonds occur when the pair of shared electrons is in an area centered between the two atoms.

37. Section 9-1
Multiple Covalent Bonds
Double bonds form when two pairs of electrons are shared between two atoms.

38. Triple Covalent Bonds
Section 9-1
Triple bonds form when three pairs of electrons are shared between two atoms.

39. Multiple Covalent Bonds (cont.)
Section 9-1
A multiple covalent bond consists of one sigma bond and at least one pi bond.
The pi bond is formed when parallel orbitals overlap and share electrons.

40. The Strength of Covalent Bonds
Section 9-1
The strength depends on the distance between the two nuclei, or bond length.
As length increases, strength decreases.

41. Section 9-1
The Strength of Covalent Bonds (cont.)
The amount of energy required to break a bond is called the bond dissociation energy.
The shorter the bond length, the greater the energy required to break it.

42. The Strength of Covalent Bonds (cont.)
Section 9-1
An endothermic reaction is one where a greater amount of energy is required to break a bond in reactants than is released when the new bonds form in the products.
An exothermic reaction is one where more energy is released than is required to break the bonds in the initial reactants.

43. The Covalent Bond
Standard: 2a,2b, 2e, 7b Article: Mastering Concepts: 272 (72-76) Terms: Practice Problems: 244 (1-5)
Using a Venn diagram show the difference between ionic, covalent and metallic (3 stars)
Homework:
Cornell Notes: 9.1
Section Assessment: 247(6-11)
Mastering Problems: 272 (88-92) Stamps

44. Mastering Concepts: 272 (72-76)
72. What is the octet rule, and how is it used in covalent bonding? (9.1) Atoms lose, gain, or share electrons to end with a full outer energy level. Certain atoms share electrons to achieve an octet.

45. Mastering Concepts: 272 (72-76)
73. Describe the formation of a covalent bond. (9.1) The nucleus of one atom attracts the electrons of the other atom, and they share one or more pairs of electrons.

46. Mastering Concepts: 272 (72-76)
74. Describe the bonding in molecules. (9.1) Molecules bond covalently.

47. Mastering Concepts: 272 (72-76)
75. Describe the forces, both attractive and repulsive, that occur as two atoms come closer together. (9.1) See Figure 9-1 on page 242.

48. Reasonable distance between atoms to avoid repulsion between two positive nuclei

49. Mastering Concepts: 272 (72-76)
76. How could you predict the presence of a sigma or pi bond in a molecule? (9.1) single bond: sigma bond; double bond: a sigma bond and a pi bond; triple bond: one sigma and two pi bonds

50. The Covalent Bond
Standard: 2a,2b, 2e, 7b Article: Mastering Concepts: 272 (72-76) Terms: Practice Problems: 244 (1-5)
Using a Venn diagram show the difference between ionic, covalent and metallic (3 stars)
Homework:
Cornell Notes: 9.1
Section Assessment: 247(6-11)
Mastering Problems: 272 (88-92) Stamps

51. Practice Problems: 244 (1-5)
Draw the Lewis structure for each of these molecules.
PH3
H2S
HCl
CCl4
SiH4

52. 1) total valance electrons 5+3 (1) = 8
Compound
1.PH3
4) Octet for outer atoms H P
H H
1) total valance electrons
5+3 (1) = 8
5) Remaining e– s on center atom P:
2) Skeletal Structure
H H
6) Create multiple bonds?
none
3) Electron pairs in bonds
8-6=2
Final structure

53. 1) total valance electrons 2(1) +6 = 8
Compound
2. H2S
4) Octet for outer atoms
H S H
1) total valance electrons
2(1) +6 = 8
5) Remaining e– s on center atom ..
2) Skeletal Structure
6) Create multiple bonds?
none
3) Electron pairs in bonds
8-4=4
Final structure

54. 1) total valance electrons 1+ 7 = 8 5) Remaining e– s on center atom
Compound
3. HCl
4) Octet for outer atoms ..
H − Cl :
1) total valance electrons
1+ 7 = 8
5) Remaining e– s on center atom
2) Skeletal Structure
H − Cl
6) Create multiple bonds?
none
3) Electron pairs in bonds
8-2=6
Final structure

55. 3) Electron pairs in bonds
Compound
4.CCl4
3) Electron pairs in bonds
32 – 8=24
1) total valance electrons
4+4 (7) = 32
4) Octet for outer atoms ..
:Cl:
: Cl C Cl :
: C:
2) Skeletal Structure Cl
Cl C Cl

56. 3) Electron pairs in bonds
Compound
5.SiH4
3) Electron pairs in bonds
8 – 8=0
1) total valance electrons
4+4 (1) = 8
4) Octet for outer atoms H
H Si H .
2) Skeletal Structure
H Si H