5.     Classes of Overall Transformations

6.     Classes of Mechanisms 

o    Polar Mechanisms

§  Nucleophiles

§  Electrophiles and Leaving Groups

§  Acidic and Basic Conditions; The pK_a Rule

§  A Typical Polar Mechanism

o    Free-Radical Mechanisms

o    Pericyclic Mechanisms

o    Transition-Metal-Catalyzed and -Mediated Mechanisms

7.     Summary

8.    End of Chapter Problems

Chapter 2. Polar Reactions under Basic Conditions.

1.    Introduction to Substitution and Elimination

o    Substitution by the S_N2 Mechanism

o    β-Elimination by the E2 and E1cb Mechanisms

o    Predicting Substitution vs. Elimination

2.     Addition of Nucleophiles to Electrophilic π Bonds

o    Addition to Carbonyl Compounds

o    Conjugate Addition; The Michael Reaction

3.     Substitution at C(sp²)–X  s Bonds

o    Substitution at Carbonyl C

o    Substitution at Alkenyl and Aryl C

o    Metal Insertion; Halogen–Metal Exchange

4.     Substitution and Elimination at C(sp³)–X σ Bonds

o    Substitution by the S_RN1 Mechanism

o    Substitution by the Elimination–Addition Mechanism

o    Substitution by the One-Electron Transfer Mechanism

o    Metal Insertion; Halogen–Metal Exchange

o    α-Elimination; Generation and Reactions of Carbenes

5.     Base-Promoted Rearrangements

o    Migrations from C to C

o    Migrations from C to O

o    Migrations from C to  N

o    Migrations from B to C or O

6.     Two Multistep Reactions

o   The Swern Oxidation

o   The Mitsunobu Reaction

7.     Summary

8.    End of Chapter Problems

Chapter 3. Polar Reactions under Acidic Conditions.

1.     Carbocations

o    Carbocation Stability

o    Carbocation Generation; The Role of Protonation

o    Typical Reactions of Carbocations; Rearrangements

2.     Substitution and β-Elimination Reactions at C(sp³)–X

o    Substitution by the S_N1 and S_N2 Mechanisms

o    Elimination by the E1 Mechanism

o    Predicting Substitution vs. Elimination

3.     Electrophilic Addition to Nucleophilic C=C π Bonds

4.     Substitution at Nucleophilic C=C π Bonds

o    Electrophilic Aromatic Substitution

o    Aromatic Substitution of Anilines via Diazonium Salts

o    Electrophilic Aliphatic Substitution

5.     Nucleophilic Addition to and Substitution at Electrophilic π Bonds.

o    Heteroatom Nucleophiles

o    Carbon Nucleophiles

6.     Catalysis Involving Iminium Ions

7.     Summary

8.    End of Chapter Problems

Chapter 4. Pericyclic Reactions.

1.     Introduction

o    Classes of Pericyclic Reactions

o    Polyene MOs

2.     Electrocyclic Reactions

o    Typical Reactions

o    Stereospecificity

o    Stereoselectivity 

3.     Cycloadditions

o    Typical Reactions

§  The Diels–Alder Reaction

§  Other Cycloadditions

o    Regioselectivity 

o    Stereospecificity

o    Stereoselectivity 

4.     Sigmatropic Rearrangements

o    Typical Reactions

o    Stereospecificity 

o    Stereoselectivity

5.     Ene Reactions.

6.     Summary

7.    End of Chapter Problems

Chapter 5. Free Radical Reactions.

1.     Free Radicals

o    Stability

o    Generation from Closed-Shell Species

o    Typical Reactions

o    Chain vs. Nonchain Mechanisms

2.     Chain Free-Radical Reactions

o    Substitution Reactions

o    Addition and Fragmentation Reactions

§  Carbon-Heteroatom Bond-Forming Reactions

§  Carbon-Carbon Bond-Forming and -Cleaving Reactions

3.     Nonchain Free-Radical Reactions

o    Photochemical Reactions

o    Reductions and Oxidations with Metals

§  Addition of H2 across π Bonds 

§  Reduction of C-X Bonds. Reductive Coupling

§  One-Electron Oxidations

 o    Cycloaromatizations

4.     Miscellaneous Radical Reactions

o    1,2-Anionic Rearrangements; Lone-Pair Inversion

o    Triplet Carbenes and Nitrenes

5.     Summary

6.    End of Chapter Problems

Chapter 6. Transition-Metal-Mediated and -Catalyzed Reactions.

1.     Introduction to the Chemistry of Transition Metals

o    Conventions of Drawing Structures

o    Counting Electrons

§  Typical Ligands; Total Electron Count

§  Oxidation State and d Electron Count

o    Typical Reactions

o    Stoichiometric vs. Catalytic Mechanisms

2.     Addition Reactions

o    Late-Metal-Catalyzed Hydrogenation and Hydrometallation (Pd, Pt, Rh)

o    Hydroformylation (Co, Rh)

o    Hydrozirconation (Zr)

o    Alkene Polymerization (Ti, Zr, Sc, and others)

o    Cyclopropanation, Epoxidation, and Aziridination of Alkenes (Cu, Rh, Mn, Ti)

o    Dihydroxylation and Aminohydroxylation of Alkenes (Os)

o    Nucleophilic Addition to Alkenes and Alkynes (Hg, Pd)

o    Conjugate Addition Reactions (Cu)

o    Reductive Coupling Reactions (Ti, Zr)

o    Pauson–Khand Reaction (Co)

o    Dötz Reaction (Cr)

o    Metal-Catalyzed Cycloaddition and Cyclotrimerization (Co, Ni, Rh)

3.     Substitution Reactions

o    Hydrogenolysis (Pd)

o    Carbonylation of Alkyl Halides (Pd, Rh)

o    Heck Reaction (Pd)

o    Metal-Caatalyzed Nucleophilic Substitution Reactions: Kumada, Stille, Suzuki, Negishi, Buchwald–Hartwig, Sonogashira, and Ullmann Reactions (Ni, Pd, Cu)

o    Allylic Substitution (Pd)

o    Pd-Catalyzed Nucleophilic Substitution of Alkenes; Wacker Oxidation

o    C–H Activation (Pd, Ru, Rh)

o    Tebbe Reaction (Ti)

o    Propargyl Substitution in Co–Alkyne Complexes

4.     Rearrangement Reactions

o    Alkene Isomerization (Rh)

o    Olefin and Alkyne Metathesis (Ru, W, Mo, Ti)

5.     Elimination Reactions

o    Oxidation of Alcohols (Cr, Ru)

o    Decarbonylation of Aldehydes (Rh)

6.     Summary

7.     End of Chapter Problems

Chapter 7. Mixed Mechanism Problems.