Chapter 2 (CIC) and Chapter 8 (CTCS)

1. Chapter 2 (CIC) and Chapter 8 (CTCS) • Read in CTCS Chapter 8.1, 4, 6-8 • Problems in CTCS: 3, 31, 33, 47abcdf, 49bd, 51a, 59bd, 61

2. Ozone • A pollutant in troposphere • A filter of UV light in stratosphere • 3 O2(g) + Energy  2 O3(g) • Energy = lightning, photocopier, electric arc, etc. • Allotrope (e.g., graphite, diamond, fullerene) • Used for bleaching (wood, fabric, water) • Why is ozone different from oxygen and why is it helpful in one part of our atmosphere but not in another?

3. Periodic Table • Why is periodic table laid out the way it is? • Li, Na, K demo • Valence electrons (e-) – account for chemical and physical properties of elements and are the outermost electrons of an atom • Can be determined for any representative element by the number above the Group (Family) in the periodic table (1A-8A) • Families: Alkali metal, Alkaline Earth, Chalcogen, Halogen, Noble Gas

4. Getting to Low Energy • Noble Gas – “inert” because it is stable by itself • These elements have 8 valence e- (except He) • Other elements try to attain this low energy state as well • Elements do this by gaining, losing, or sharing e- • Sharing of e- yields covalent bonds

5. Lewis Structures • Lewis symbols • Two H· atoms can share their electron so that each looks like He (noble gas) • The line between H’s is shorthand for 2 e- and is called a single bond

6. In the case of fluorine gas (F2), each atom can share an e- so that at any point in time, either atom can look like neon (It follows the Octet Rule) • This structure has both bonding and nonbonding e- pairs • Q: Draw Lewis structures for Cl2 and CH4

7. Multiple Bonds • For a Lewis structure of O2 each O needs two e- to supplement the 6 valence e- of oxygen • This requires a sharing of 4 e- total • Oftentimes the nonbonding e- on Lewis structures are not shown • This molecule has a double bond • These are shorter, stronger and harder to break

8. Rules for Lewis Structures • Count the number of valence e- • Draw a structure where the peripheral atoms surround the central atom • The central atom is usually the first atom written (S in SO42-, I in IO65-) • The central atom is usually the most metallic element • H can never be the central atom because it can only have a duet meaning one bond • When H and O exist in the same molecule, the H is usually attached to the O atom (H2CO3) 3. Draw covalent (or shared) bonds between the peripheral atoms and the central atom

9. 4. Determine the number of valence e- still available • 5. Fill the octets for the peripheral atoms. • 6. Fill the octet for the central atom (if there are enough valence e-) • If there are not enough e- to accomplish #6, make multiple bonds between the central and peripheral atoms • You should check two things when finished: • 1. Are you showing the correct number of valence e-? • 2. Does each atom have an octet?

10. Draw Lewis Structures for CO2, N2, CO, PCl3, CH3OH and H2CO It doesn’t matter what the bond angles are

11. The structure of O3 • 3 x 6 = 18e- 2,3. O-O-O 4. 18 - 4 = 14e- 5. 6. 7. *These are not linear molecules

12. Resonance • These two structures are averaged together to get the “actual” structure and they are referred to as resonance structures • The actual structure has an O-O bond length of 1.28Å compared to an O-O typically at 1.47Å and O=O at 1.21Å • Resonance structures only move e-, not atoms

13. Formal Charge • Write a Lewis Structure for Cl2CO • How do you know which one is closer to reality? • F.C. = #valence e- - #lone pair e- - #bonds • The total sum of formal charges should be equal to the charge on the ion/molecule • You should end up with a Lewis structure that has formal charges as close to 0 as possible

14. Exceptions to Octet Rule • Write a Lewis structure for NO • Many exceptions exist • Odd numbered electron systems • Electron deficient atoms (Be, B, Al, etc.) • Central atom has more than 8 electrons (P, S, I, etc.) • Write a Lewis structure for BF3 and calculate formal charges. How does it react with NH3?