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Next Steps:. Resonance. Formal Charge. When atoms do not exhibit ‘normal’ bonding patterns, they will contain a ‘formal charge’. Formal Charge does not indicate an actual ionic charge – it indicates the distribution of electrons. Dimethyl Sulfoxide (DMSO).
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Next Steps: Resonance
Formal Charge • When atoms do not exhibit ‘normal’ bonding patterns, they will contain a ‘formal charge’. • Formal Charge does not indicate an actual ionic charge – it indicates the distribution of electrons
DimethylSulfoxide (DMSO) Normally, Sulfur owns 6 valence electrons, but in this structure, it only owns 5 Therefore, Sulfur has formally lost 1 electron and has a + charge Likewise, Oxygen normally owns 6 valence electrons – in this structure it owns 7, so it has a formal - charge
Calculating Formal Charge FC = #valence e- - [(1/2 bonded e-) + nonbonding e-] Easier Calculation: FC = #valence e- - bonds – dots You Try It: Calculate any fc’s for nonhydrogen atoms H3C-C≡N-O
Note: • From now on, lone pairs or formal charges must be shown when needed. • You may show both, but it is not necessary. • Atoms that exhibit normal bonding patterns may assumed to have a formal charge of zero Read pages 10-19 & try problems
Resonance • This is why we study formal charge: Consider Nitromethane:
Nitromethane EPM • Experiments show that each N-O bond is equivalent. Examine electron distribution:
Why? • The true structure is a resonance hybrid. The electrons are distributed evenly with both oxygen atoms bearing equal negative charge. • Remember: • Resonance structures are not real. They only help us to envision electron distribution. Only by knowing the contributing structures can we envision the real structure.
2 Major Rules for Resonance • Never break a single bond • Never exceed an octet for 2nd row elements For more practice see handout problems 2.2 – 2.12 pgs 26-27
Drawing Arrows to Show Movement of Electrons: Pushing Electrons Where the electrons are moving to Where the electrons come from
You try it • Draw arrows that show how one structure becomes the other through resonance: More problems: pg 29; 2.14 – 2.19
Patterns for Drawing Resonance Structures: • Lone pair next to pi bond • Lone pair next to a positive charge • Pi bond next to a positive charge • Pi bond between two atom where one of those is electronegative • Pi bonds going all the way around a ring • Pi bond next to a free radical
1. Lone Pair Next to a Pi Bond • “Next to” – a lone pair is separated from a pi bond by exactly one single bond
2. Lone pair next to + charge • Remember a + charge means that there is less electron density than usual, so there is an empty orbital available
4. Pi Bond between two atoms where one is electronegative • An electronegative atom can support an additional pair of electrons and a formal negative charge
Phenanthrene • How many resonance structures for this example?
6. Pi bond next to free radical • What is a free radical? • radical - (free radical) a neutral substance that contains a single, unpaired electron in one of its orbitals, denoted by a dot (·) leaving it with an odd number of electrons. • Radicals are highly reactive and unstable • Radicals can form from stable molecules and can also react with each other.
Showing resonance of free radicals • Use half-arrows to represent the movement of single electrons
You try it • Show all of the resonance forms for the following structure:
A look at Pyridine The lone pair on the nitrogen does not participate in resonance due to its position in an sp2 hybrid orbital
Significant Resonance Structures • Not all resonance structures are significant. Three rules help us choose structures that are significant • 1. Minimize Charges • 2. Electronegative atoms can bear positive charge only if they have a full octet • 3. Avoid resonance structures in which two carbon atoms bear opposite charges