Organic chemistry

Organic Chemistry, 11th Edition continues its tradition of excellence in teaching and preparing students for success in the organic classroom and beyond. A central theme of the authors' approach to organic chemistry is to emphasize the relationship between structure and reactivity. To accomplish this, the text is organized in a way that combines the most useful features of a functional group approach with one largely based on reaction mechanisms. Emphasizing mechanisms and their common aspects as often as possible, this book shows students what organic chemistry is, how it works, and what it does in living systems and the physical world around us.

1 The Basics Bonding and Molecular Structure 1 1.1 Life and the Chemistry of Carbon Compounds-We are Stardust 2 1.2 Atomic Structure 3 1.3 Chemical Bonds: The Octet Rule 5 1.4 How To Write Lewis Structures 7 1.5 Formal Charges and How To Calculate Them 12 1.6 Isomers: Different Compounds that Have the Same Molecular Formula 14 1.7 How To Write and Interpret Structural Formulas 15 1.8 Resonance Theory 22 1.9 Quantum Mechanics and Atomic Structure 27 1.10 Atomic Orbitals and Electron Configuration 28 1.11 Molecular Orbitals 30 1.12 The Structure of Methane and Ethane: sp3 Hybridization 32 1.13 The Structure of Ethene (Ethylene): sp2 Hybridization 36 1.14 The Structure of Ethyne (Acetylene): sp Hybridization 40 1.15 A Summary of Important Concepts That Come from Quantum Mechanics 43 1.16 How To Predict Molecular Geometry: The Valence Shell Electron Pair Repulsion Model 44 1.17 Applications of Basic Principles 47 2 Families of Carbon Compounds Functional Groups, Intermolecular Forces, and Infrared (IR ) Spectroscopy 55 2.1 Hydrocarbons: Representative Alkanes, Alkenes, Alkynes, and Aromatic Compounds 56 2.2 Polar Covalent Bonds 59 2.3 Polar and Nonpolar Molecules 61 2.4 Functional Groups 64 2.5 Alkyl Halides or Haloalkanes 65 2.6 Alcohols and Phenols 67 2.7 Ethers 69 2.8 Amines 70 2.9 Aldehydes and Ketones 71 2.10 Carboxylic Acids, Esters, and Amides 73 2.11 Nitriles 75 2.12 Summary of Important Families of Organic Compounds 76 2.13 Physical Properties and Molecular Structure 77 2.14 Summary of Attractive Electric Forces 85 2.15 Infrared Spectroscopy: An Instrumental Method for Detecting Functional Groups 86 2.16 Interpreting IR Spectra 90 2.17 Applications of Basic Principles 97 3 Acids and Bases An Introduction to Organic Reactions and Their Mechanisms 104 3.1 Acid-Base Reactions 105 3.2 How To Use Curved Arrows in Illustrating Reactions 107 3.3 Lewis Acids and Bases 109 3.4 Heterolysis of Bonds to Carbon: Carbocations and Carbanions 111 3.5 The Strength of Bronsted-Lowry Acids and Bases: Ka and pKa 113 3.6 How To Predict the Outcome of Acid-Base Reactions 118 3.7 Relationships Between Structure and Acidity 120 3.8 Energy Changes 123 3.9 The Relationship Between the Equilibrium Constant and the Standard Free-Energy Change, DG8 125 3.10 Acidity: Carboxylic Acids versus Alcohols 126 3.11 The Effect of the Solvent on Acidity 130 3.12 Organic Compounds as Bases 130 3.13 A Mechanism for an Organic Reaction 132 3.14 Acids and Bases in Nonaqueous Solutions 133 3.15 Acid-Base Reactions and the Synthesis of Deuterium- and Tritium-Labeled Compounds 134 3.16 Applications of Basic Principles 135 4 Nomenclature and Conformations of Alkanes and Cycloalkanes 142 4.1 Introduction to Alkanes and Cycloalkanes 143 4.2 Shapes of Alkanes 144 4.3 How To Name Alkanes, Alkyl Halides, and Alcohols: The Iupac System 146 4.4 How To Name Cycloalkanes 153 4.5 How To Name Alkenes and Cycloalkenes 156 4.6 How To Name Alkynes 158 4.7 Physical Properties of Alkanes and Cycloalkanes 159 4.8 Sigma Bonds and Bond Rotation 162 4.9 Conformational Analysis of Butane 164 The Chemistry of ... Muscle Action 166 4.10 The Relative Stabilities of Cycloalkanes: Ring Strain 167 4.11 Conformations of Cyclohexane: The Chair and the Boat 168 4.12 Substituted Cyclohexanes: Axial and Equatorial Hydrogen Groups 171 4.13 Disubstituted Cycloalkanes: Cis-Trans Isomerism 175 4.14 Bicyclic and Polycyclic Alkanes 179 4.15 Chemical Reactions of Alkanes 180 4.16 Synthesis of Alkanes and Cycloalkanes 180 4.17 How To Gain Structural Information from Molecular Formulas and the Index of Hydrogen Deficiency 182 4.18 Applications of Basic Principles 184 5 Stereochemistry Chiral Molecules 191 5.1 Chirality and Stereochemistry 192 5.2 Isomerism: Constitutional Isomers and Stereoisomers 193 5.3 Enantiomers and Chiral Molecules 195 5.4 Molecules Having One Chirality Center are Chiral 196 5.5 More about the Biological Importance of Chirality 199 5.6 How To Test for Chirality: Planes of Symmetry 201 5.7 Naming Enantiomers: The R,S-System 202 5.8 Properties of Enantiomers: Optical Activity 206 5.9 The Origin of Optical Activity 211 5.10 The Synthesis of Chiral Molecules 213 5.11 Chiral Drugs 215 5.12 Molecules with More than One Chirality Center 217 5.13 Fischer Projection Formulas 223 5.14 Stereoisomerism of Cyclic Compounds 225 5.15 Relating Configurations through Reactions in which No Bonds to the Chirality Center Are Broken 227 5.16 Separation of Enantiomers: Resolution 231 5.17 Compounds with Chirality Centers Other than Carbon 232 5.18 Chiral Molecules That Do Not Possess a Chirality Center 232 6 Ionic Reactions Nucleophilic Substitution and Elimination Reactions of Alkyl Halides 239 6.1 Alkyl Halides 240 6.2 Nucleophilic Substitution Reactions 241 6.3 Nucleophiles 243 6.4 Leaving Groups 245 6.5 Kinetics of a Nucleophilic Substitution Reaction: An SN2 Reaction 245 6.6 A Mechanism for the SN2 Reaction 246 6.7 Transition State Theory: Free-Energy Diagrams 248 6.8 The Stereochemistry of SN2 Reactions 251 6.9 The Reaction of Tert-Butyl Chloride with Water: An SN1 Reaction 253 6.10 A Mechanism for the SN1 Reaction 254 6.11 Carbocations 256 6.12 The Stereochemistry of SN1 Reactions 258 6.13 Factors Affecting the Rates of SN1 and SN2 Reactions 261 6.14 Organic Synthesis: Functional Group Transformations Using SN2 Reactions 271 6.15 Elimination Reactions of Alkyl Halides 275 6.16 The E2 Reaction 276 6.17 The E1 Reaction 278 6.18 How To Determine Whether Substitution or Elimination Is Favored 280 6.19 Overall Summary 282 7 Alkenes and Alkynes I Properties and Synthesis. Elimination Reactions of Alkyl Halides 291 7.1 Introduction 292 7.2 The (E)-(Z) System for Designating Alkene Diastereomers 292 7.3 Relative Stabilities of Alkenes 293 7.4 Cycloalkenes 296 7.5 Synthesis of Alkenes via Elimination Reactions 296 7.6 Dehydrohalogenation of Alkyl Halides 297 7.7 Acid-Catalyzed Dehydration of Alcohols 303 7.8 Carbocation Stability and the Occurrence of Molecular Rearrangements 309 7.9 The Acidity of Terminal Alkynes 313 7.10 Synthesis of Alkynes by Elimination Reactions 314 7.11 Terminal Alkynes Can Be Converted to Nucleophiles for Carbon-Carbon Bond Formation 316 7.12 Hydrogenation of Alkenes 318 7.13 Hydrogenation: The Function of the Catalyst 320 7.14 Hydrogenation of Alkynes 321 7.15 An Introduction to Organic Synthesis 323 8 Alkenes and Alkynes II Addition Reactions 337 8.1 Addition Reactions of Alkenes 338 8.2 Electrophilic Addition of Hydrogen Halides to Alkenes: Mechanism and Markovnikov's Rule 340 8.3 Stereochemistry of the Ionic Addition to an Alkene 345 8.4 Addition of Water to Alkenes: Acid-Catalyzed Hydration 346 8.5 Alcohols from Alkenes through Oxymercuration- Demercuration: Markovnikov Addition 349 8.6 Alcohols from Alkenes through Hydroboration-Oxidation: Anti-Markovnikov Syn Hydration 352 8.7 Hydroboration: Synthesis of Alkylboranes 353 8.8 Oxidation and Hydrolysis of Alkylboranes 355 8.9 Summary of Alkene Hydration Methods 358 8.10 Protonolysis of Alkylboranes 359 8.11 Electrophilic Addition of Bromine and Chlorine to Alkenes 359 8.12 Stereospecific Reactions 363 8.13 Halohydrin Formation 364 8.14 Divalent Carbon Compounds: Carbenes 366 8.15 Oxidation of Alkenes: Syn 1,2-Dihydroxylation 368 8.16 Oxidative Cleavage of Alkenes 371 8.17 Electrophilic Addition of Bromine and Chlorine to Alkynes 374 8.18 Addition of Hydrogen Halides to Alkynes 374 8.19 Oxidative Cleavage of Alkynes 375 8.20 How to Plan a Synthesis: Some Approaches and Examples 376 9 Nuclear Magnetic Resonance and Mass Spectrometry Tools for Structure Determination 391 9.1 Introduction 392 9.2 Nuclear Magnetic Resonance (NMR) Spectroscopy 392 9.3 How To Interpret Proton NMR Spectra 398 9.4 Nuclear Spin: The Origin of the Signal 401 9.5 Detecting the Signal: Fourier Transform NMR Spectrometers 403 9.6 The Chemical Shift 405 9.7 Shielding and Deshielding of Protons 406 9.8 Chemical Shift Equivalent and Nonequivalent Protons 408 9.9 Signal Splitting: Spin-Spin Coupling 411 9.10 Proton NMR Spectra and Rate Processes 420 9.11 Carbon-13 NMR Spectroscopy 422 9.12 Two-Dimensional (2D) NMR Techniques 428 9.13 An Introduction to Mass Spectrometry 431 9.14 Formation of Ions: Electron Impact Ionization 432 9.15 Depicting the Molecular Ion 432 9.16 Fragmentation 433 9.17 Isotopes in Mass Spectra 440 9.18 GC/MS Analysis 443 9.19 Mass Spectrometry of Biomolecules 444 10 Radical Reactions 457 10.1 Introduction: How Radicals Form and How They React 458 10.2 Homolytic Bond Dissociation Energies (DH8) 460 10.3 Reactions of Alkanes with Halogens 463 10.4 Chlorination of Methane: Mechanism of Reaction 465 10.5 Halogenation of Higher Alkanes 468 10.6 The Geometry of Alkyl Radicals 471 10.7 Reactions That Generate Tetrahedral Chirality Centers 471 10.8 Allylic Substitution and Allylic Radicals 475 10.9 Benzylic Substitution and Benzylic Radicals 478 10.10 Radical Addition to Alkenes: The Anti-Markovnikov Addition of Hydrogen Bromide 481 10.11 Radical Polymerization of Alkenes: Chain-Growth Polymers 483 10.12 Other Important Radical Reactions 487 11 Alcohols and Ethers Synthesis and Reactions 498 11.1 Structure and Nomenclature 499 11.2 Physical Properties of Alcohols and Ethers 501 11.3 Important Alcohols and Ethers 503 11.4 Synthesis of Alcohols from Alkenes 505 11.5 Reactions of Alcohols 507 11.6 Alcohols as Acids 509 11.7 Conversion of Alcohols into Alkyl Halides 510 11.8 Alkyl Halides from the Reaction of Alcohols with Hydrogen Halides 510 11.9 Alkyl Halides from the Reaction of Alcohols with PBr3 or SOCl2 513 11.10 Tosylates, Mesylates, and Triflates: Leaving Group Derivatives of Alcohols 514 11.11 Synthesis of Ethers 517 11.12 Reactions of Ethers 522 11.13 Epoxides 523 11.14 Reactions of Epoxides 525 11.15 Anti 1,2-Dihydroxylation of Alkenes via Epoxides 528 11.16 Crown Ethers 531 11.17 Summary of Reactions of Alkenes, Alcohols, and Ethers 532 12 Alcohols from Carbonyl Compounds Oxidation-Reduction and Organometallic Compounds 542 12.1 Structure of the Carbonyl Group 543 12.2 Oxidation-Reduction Reactions in Organic Chemistry 544 12.3 Alcohols by Reduction of Carbonyl Compounds 546 12.4 Oxidation of Alcohols 551 12.5 Organometallic Compounds 556 12.6 Preparation of Organolithium and Organomagnesium Compounds 557 12.7 Reactions of Organolithium and Organomagnesium Compounds 558 12.8 Alcohols from Grignard Reagents 561 12.9 Protecting Groups 570 13 Conjugated Unsaturated Systems 581 13.1 Introduction 582 13.2 The Stability of the Allyl Radical 582 13.3 The Allyl Cation 586 13.4 Resonance Theory Revisited 587 13.5 Alkadienes and Polyunsaturated Hydrocarbons 591 13.6 1,3-Butadiene: Electron Delocalization 592 13.7 The Stability of Conjugated Dienes 595 13.8 Ultraviolet-Visible Spectroscopy 596 13.9 Electrophilic Attack on Conjugated Dienes: 1,4-Addition 604 13.10 The Diels-Alder Reaction: A 1,4-Cycloaddition Reaction of Dienes 608 14 Aromatic Compounds 626 14.1 The Discovery of Benzene 627 14.2 Nomenclature of Benzene Derivatives 628 14.3 Reactions of Benzene 630 14.4 The Kekule Structure for Benzene 631 14.5 The Thermodynamic Stability of Benzene 632 14.6 Modern Theories of the Structure of Benzene 634 14.7 Huckel's Rule: The 4n + 2 p Electron Rule 637 14.8 Other Aromatic Compounds 645 14.9 Heterocyclic Aromatic Compounds 648 14.10 Aromatic Compounds in Biochemistry 650 14.11 Spectroscopy of Aromatic Compounds 652 15 Reactions of Aromatic Compounds 669 15.1 Electrophilic Aromatic Substitution Reactions 670 15.2 A General Mechanism for Electrophilic Aromatic Substitution 671 15.3 Halogenation of Benzene 673 15.4 Nitration of Benzene 674 15.5 Sulfonation of Benzene 675 15.6 Friedel-Crafts Alkylation 676 15.7 Friedel-Crafts Acylation 678 15.8 Limitations of Friedel-Crafts Reactions 680 15.9 Synthetic Applications of Friedel-Crafts Acylations: The Clemmensen and Wolff-Kishner Reductions 683 15.10 Substituents Can Affect Both the Reactivity of the Ring and the Orientation of the Incoming Group 685 15.11 How Substituents Affect Electrophilic Aromatic Substitution: A Closer Look 690 15.12 Reactions of the Side Chain of Alkylbenzenes 699 15.13 Alkenylbenzenes 702 15.14 Synthetic Applications 704 15.15 Allylic and Benzylic Halides in Nucleophilic Substitution Reactions 708 15.16 Reduction of Aromatic Compounds 710 16 Aldehydes and Ketones Nucleophilic Addition to the Carbonyl Group 720 16.1 Introduction 721 16.2 Nomenclature of Aldehydes and Ketones 721 16.3 Physical Properties 723 16.4 Synthesis of Aldehydes 724 16.5 Synthesis of Ketones 729 16.6 Nucleophilic Addition to the Carbon-Oxygen Double Bond 732 16.7 The Addition of Alcohols: Hemiacetals and Acetals 735 16.8 The Addition of Primary and Secondary Amines 741 16.9 The Addition of Hydrogen Cyanide: Cyanohydrins 746 16.10 The Addition of Ylides: The Wittig Reaction 747 16.11 Oxidation of Aldehydes 751 16.12 The Baeyer-Villiger Oxidation 751 16.13 Chemical Analyses for Aldehydes and Ketones 753 16.14 Spectroscopic Properties of Aldehydes and Ketones 753 16.15 Summary of Aldehyde and Ketone Addition Reactions 756 17 Carboxylic Acids and Their Derivatives Nucleophilic Addition-Elimination at the Acyl Carbon 771 17.1 Introduction 772 17.2 Nomenclature and Physical Properties 772 17.3 Preparation of Carboxylic Acids 781 17.4 Acyl Substitution: Nucleophilic Addition-Elimination at the Acyl Carbon 784 17.5 Acyl Chlorides 786 17.6 Carboxylic Acid Anhydrides 788 17.7 Esters 789 17.8 Amides 796 17.9 Derivatives of Carbonic Acid 802 17.10 Decarboxylation of Carboxylic Acids 805 17.11 Chemical Tests for Acyl Compounds 807 17.12 Polyesters and Polyamides: Step-Growth Polymers 807 17.13 Summary of the Reactions of Carboxylic Acids and Their Derivatives 809 18 Reactions at the A Carbon of Carbonyl Compounds Enols and Enolates 821 18.1 The Acidity of the a Hydrogens of Carbonyl Compounds: Enolate Anions 822 18.2 Keto and Enol Tautomers 823 18.3 Reactions via Enols and Enolates 825 18.4 Lithium Enolates 831 18.5 Enolates of b-Dicarbonyl Compounds 834 18.6 Synthesis of Methyl Ketones: The Acetoacetic Ester Synthesis 835 18.7 Synthesis of Substituted Acetic Acids: The Malonic Ester Synthesis 840 18.8 Further Reactions of Active Hydrogen Compounds 844 18.9 Synthesis of Enamines: Stork Enamine Reactions 844 18.10 Summary of Enolate Chemistry 847 19 Condensation and Conjugate Addition Reactions of Carbonyl Compounds More Chemistry of Enolates 858 19.1 Introduction 859 19.2 The Claisen Condensation: A Synthesis of b-Keto Esters 859 19.3 b-Dicarbonyl Compounds by Acylation of Ketone Enolates 864 19.4 Aldol Reactions: Addition of Enolates and Enols to Aldehydes and Ketones 865 19.5 Crossed Aldol Condensations 871 19.6 Cyclizations via Aldol Condensations 876 19.7 Additions to a,b-Unsaturated Aldehydes and Ketones 877 19.8 The Mannich Reaction 882 19.9 Summary of Important Reactions 884 20 Amines 897 20.1 Nomenclature 898 20.2 Physical Properties and Structure of Amines 899 20.3 Basicity of Amines: Amine Salts 901 20.4 Preparation of Amines 908 20.5 Reactions of Amines 917 20.6 Reactions of Amines with Nitrous Acid 918 20.7 Replacement Reactions of Arenediazonium Salts 920 20.8 Coupling Reactions of Arenediazonium Salts 924 20.9 Reactions of Amines with Sulfonyl Chlorides 926 20.10 Synthesis of Sulfa Drugs 928 20.11 Analysis of Amines 929 20.12 Eliminations Involving Ammonium Compounds 931 20.13 Summary of Preparations and Reactions of Amines 932 21 Phenols and Aryl Halides Nucleophilic Aromatic Substitution 944 21.1 Structure and Nomenclature of Phenols 945 21.2 Naturally Occurring Phenols 946 21.3 Physical Properties of Phenols 947 21.4 Synthesis of Phenols 947 21.5 Reactions of Phenols as Acids 949 21.6 Other Reactions of the OiH Group of Phenols 952 21.7 Cleavage of Alkyl Aryl Ethers 952 21.8 Reactions of the Benzene Ring of Phenols 953 21.9 The Claisen Rearrangement 956 21.10 Quinones 957 21.11 Aryl Halides and Nucleophilic Aromatic Substitution 959 21.12 Spectroscopic Analysis of Phenols and Aryl Halides 966 22 Carbohydrates 979 22.1 Introduction 980 22.2 Monosaccharides 982 22.3 Mutarotation 987 22.4 Glycoside Formation 988 22.5 Other Reactions of Monosaccharides 990 22.6 Oxidation Reactions of Monosaccharides 994 22.7 Reduction of Monosaccharides: Alditols 999 22.8 Reactions of Monosaccharides with Phenylhydrazine: Osazones 999 22.9 Synthesis and Degradation of Monosaccharides 1000 22.10 The d Family of Aldoses 1002 22.11 Fischer's Proof of the Configuration of d-(+)-Glucose 1003 22.12 Disaccharides 1005 22.13 Polysaccharides 1009 22.14 Other Biologically Important Sugars 1013 22.15 Sugars That Contain Nitrogen 1014 22.16 Glycolipids and Glycoproteins of the Cell Surface: Cell Recognition and the Immune System 1016 22.17 Carbohydrate Antibiotics 1018 22.18 Summary of Reactions of Carbohydrates 1019 23 Lipids 1027 23.1 Introduction 1028 23.2 Fatty Acids and Triacylglycerols 1028 23.3 Terpenes and Terpenoids 1037 23.4 Steroids 1040 23.5 Prostaglandins 1049 23.6 Phospholipids and Cell Membranes 1050 23.7 Waxes 1054 24 Amino Acids and Proteins 1060 24.1 Introduction 1061 24.2 Amino Acids 1062 24.3 Synthesis of a-Amino Acids 1068 24.4 Polypeptides and Proteins 1070 24.5 Primary Structure of Polypeptides and Proteins 1073 24.6 Examples of Polypeptide and Protein Primary Structure 1077 24.7 Polypeptide and Protein Synthesis 1080 24.8 Secondary, Tertiary, and Quaternary Structures of Proteins 1086 24.9 Introduction to Enzymes 1090 24.10 Lysozyme: Mode of Action of an Enzyme 1092 24.11 Serine Proteases 1094 24.12 Hemoglobin: A Conjugated Protein 1096 24.13 Purification and Analysis of Polypeptides and Proteins 1098 24.14 Proteomics 1100 25 Nucleic Acids and Protein Synthesis 1105 25.1 Introduction 1106 25.2 Nucleotides and Nucleosides 1107 25.3 Laboratory Synthesis of Nucleosides and Nucleotides 1110 25.4 Deoxyribonucleic Acid: DNA 1113 25.5 RNA and Protein Synthesis 1120 25.6 Determining the Base Sequence of DNA: The Chain-Terminating (Dideoxynucleotide) Method 1128 25.7 Laboratory Synthesis of Oligonucleotides 1131 25.8 The Polymerase Chain Reaction 1133 25.9 Sequencing of the Human Genome: An Instruction Book for the Molecules of Life 1135 Answers to Selected Problems A -1 Glossary G L-1 Index I -1