There are general four ways for pushing electrons between substances Law of Electrostatics full negative full positive full negative partial positive full positive partial negative partial positive partial negative

Law of Electrostatics - Example 1 full negative full positive

Law of Electrostatics - Example 1 full negative full positive

Law of Electrostatics - Example 2 full positive partial negative

Law of Electrostatics - Example 2 full positive partial negative

Law of Electrostatics - Example 3 full negative partial positive

Law of Electrostatics - Example 3 full negative partial positive

Law of Electrostatics - Example 4 partial positive partial negative

Law of Electrostatics - Example 4 partial positive partial negative

Balancing of Reactions (rxns) A, e-, FC = Atoms, Electrons & Formal Charges Must Balance A e- FC must balance 4 carbons, 9 hydrogens 1 bromine 4 carbons, 9 hydrogens 1 bromine 14 electrons drawn 14 electrons drawn 0 zero overall charge + formal & - formal charges sum to zero overall charge 0 zero overall charge

Balancing of Reactions (rxns) A, e-, FC = Atoms, Electrons & Formal Charges Must Balance A e- FC must balance 4 carbons, 11 hydrogens 1 oxygen 4 carbons, 11 hydrogens 1 oxygen 14 electrons drawn 14 electrons drawn + formal charge + formal charge

For these reactions, are A, e-, FC balanced ??? Yes, for both rxns

Not so obvious electron pushing rxns students struggle with

Not so obvious electron pushing rxns students struggle with boron in BH3 disobeys octet rule, 8K

Not so obvious electron pushing rxns students struggle with boron in BH3 disobeys octet rule, 8K

Not so obvious electron pushing rxns students struggle with boron in BH3 disobeys octet rule, 8K boron above now obeys octet rule, 8K “Octet rule is king!”

Not so obvious electron pushing rxns students struggle with aluminum in AlH3 disobeys octet rule, 8K

Not so obvious electron pushing rxns students struggle with aluminum in AlH3 disobeys octet rule, 8K

Not so obvious electron pushing rxns students may struggle with aluminum above now obeys octet rule, 8K “Octet rule is king!” aluminum in AlH3 disobeys octet rule, 8K

Not so obvious electron pushing rxns students may struggle with. Nonbonded electron pairs love to be protonated !!!!! Which nonbonded pair of electrons below like to be protonated? carbonyl oxygen hydroxyl oxygen

Not so obvious electron pushing rxns students may struggle with. Nonbonded electron pairs love to be protonated !!!!! Which nonbonded pair of electrons below like to be protonated?

Not so obvious electron pushing rxns students may struggle with. Nonbonded electron pairs love to be protonated !!!!! Which nonbonded pair of electrons below like to be protonated?

Not so obvious electron pushing rxns students may struggle with. Nonbonded electron pairs love to be protonated !!!!! Which nonbonded pair of electrons below like to be protonated?

Not so obvious electron pushing rxns students may struggle with. Nonbonded electron pairs love to be protonated !!!!! Which nonbonded pair of electrons below like to be protonated?

Not so obvious electron pushing rxns students may struggle with. Nonbonded electron pairs love to be protonated !!!!! Which nonbonded pair of electrons below like to be protonated? Explain why the carbonyl oxygen in the first reaction preferentially gets protonated over the hydroxyl group in acetic acid. Protonation of the carbonyl in acetic acid produces a resonance stabilized intermediate where as in the other case the intermediate will have an isolated positive charge on its hydroxyl group.

Not so obvious electron pushing rxns students may struggle with

But where is the electron pair in the alkene Not so obvious electron pushing rxns students may struggle with Reactions of pi bonds in alkenes Pi bond basic because a ”pi bond” can show chemical behavior as a base according to our three definintions for acids-bases. pi bonds can behave as a Lewis base electron pair donor pi bonds can behave as a Brownsted-Lowery base H+ acceptor But where is the electron pair in the alkene capable of donating then accepting a proton? • •

The electron pair is being share between the Not so obvious electron pushing rxns students may struggle with • • The electron pair is being share between the two carbons C=C bond and the pi bond basic is capable electron donation and H+ accepting.

Not so obvious electron pushing rxns students may struggle with unstable carbocation disobeys octet rule, 8K

Ochem I Reactions - Many rxns this semester can be labeled as either: Acid-Base (Ch 2) Brownsted-Lowery - BLAB happy & know it - donate it, H+ Lewis Acid-Base Substitutions (Ch 6) radical substitutions radical stability trend Cl2/hv (nonselective) Br2/hv (selective) SN2 (Ch 11) primary halides Eliminations alkene synthesis dehydration of alcohols acid catalyzed conditions dehydrohalogation, E2 basic dehalogenation of vicinal dihalides neutral Additions (Ch 7, 8, 9) radical additions HBr/ROOR electrophilic addition pi bond basic

Reactions this semester can be labeled as: Acid-Base (Ch 2) Brownsted-Lowery - BLAB happy & know it - donate it, H+ your pKa will clearly show it Lewis Acid-Base

Reactions this semester can be labeled as: Acid-Base (Ch 2) Brownsted-Lowery - BLAB happy & know it - donate it, H+ your pKa will clearly show it Lewis Acid-Base

Reactions this semester can be labeled as: Substitutions (Ch 6) radical substitutions radical stability trend Cl2/hv (nonselective) Br2/hv (selective) SN2 (Ch 11) primary halides

Reactions this semester can be labeled as: HIGH instability Substitutions (Ch 6) radical substitutions radical stability trend Cl2/hv (nonselective) Br2/hv (selective) Groud state

Reactions this semester can be labeled as: Substitutions (Ch 6) radical substitutions radical stability trend Cl2/hv (nonselective) Br2/hv (selective)

Reactions this semester can be labeled as: Substitutions (Ch 6) radical substitutions radical stability trend Cl2/hv (nonselective) Br2/hv (selective)

Reactions this semester can be labeled as: Substitutions (Ch 6) radical substitutions radical stability trend Cl2/hv (nonselective) Br2/hv (selective)

Reactions this semester can be labeled as: Substitutions (Ch 6) radical substitutions radical stability trend Cl2/hv (nonselective) Br2/hv (selective)

Reactions this semester can be labeled as: Substitutions (Ch 6) radical substitutions radical stability trend Cl2/hv (nonselective) Br2/hv (selective)

Reactions this semester can be labeled as: Substitutions (Ch 6) radical substitutions radical stability trend Cl2/hv (nonselective) Br2/hv (selective)

Looking for CLUES CLUES Substrate conditions alkane alkene

Looking for CLUES CLUES Substrate conditions alkane alkene

Looking for CLUES CLUES Substrate conditions alkane alkene

Looking for CLUES CLUES Substrate conditions alkene Additions (Ch 7, 8, 9) radical additions HBr/ROOR electrophilic addition pi bond basic

Looking for CLUES CLUES Substrate conditions alkene Additions (Ch 7, 8, 9) radical additions HBr/ROOR electrophilic addition pi bond basic

Reactions this semester can be labeled as: Additions (Ch 7, 8, 9) radical additions HBr/ROOR electrophilic addition pi bond basic

Reactions this semester can be labeled as: Additions (Ch 7, 8, 9)

Reactions this semester can be labeled as: Additions (Ch 7, 8, 9) radical additions HBr/ROOR electrophilic addition pi bond basic

Ochem I Reactions - Many rxns this semester can be labeled as either: Eliminations alkene synthesis dehydration of alcohols acid catalyzed conditions dehydrohalogation, E2 basic dehalogenation of vicinal dihalides neutral

Reactions this semester can be labeled as: Eliminations alkene synthesis dehydration of alcohols acid catalyzed conditions dehydrohalogation, E2 basic dehalogenation of vicinal dihalides neutral

Reactions this semester can be labeled as: Eliminations alkene synthesis dehydration of alcohols acid catalyzed conditions dehydrohalogation, E2 basic dehalogenation of vicinal dihalides neutral