EP ESSENTIAL ORG.CHEM.-MOD.MASTERING    - 3rd Edition - by Bruice - ISBN 9780133858501

EP ESSENTIAL ORG.CHEM.-MOD.MASTERING
3rd Edition
Bruice
Publisher: PEARSON CO
ISBN: 9780133858501

Solutions for EP ESSENTIAL ORG.CHEM.-MOD.MASTERING

Browse All Chapters of This Textbook

Chapter 1.14 - Summary: Hybridization, Bond Lengths, Bond Strengths, And Bond AnglesChapter 1.15 - Dipole Moments Of MoleculesChapter 2 - Acids And Bases: Central To Understanding Organic ChemistryChapter 2.1 - An Introduction To Acids And BasesChapter 2.2 - Pka And PhChapter 2.3 - Organic Acids And BasesChapter 2.4 - How To Predict The Outcome Of An Acid-base ReactionChapter 2.5 - How To Determine The Position Of EquilibriumChapter 2.6 - How The Structure Of An Acid Affects Its Pka ValueChapter 2.7 - How Substituents Affect The Strength Of An AcidChapter 2.8 - An Introduction To Delocalized ElectronsChapter 2.10 - How Ph Affects The Structure Of An Organic CompoundChapter 2.11 - Buffer SolutionsChapter 3 - An Introduction To Organic CompoundsChapter 3.1 - How Alkyl Substituents Are NamedChapter 3.2 - The Nomenclature Of AlkanesChapter 3.3 - The Nomenclature Of Cycloalkanes • Skeletal StructuresChapter 3.4 - The Nomenclature Of Alkyl HalidesChapter 3.5 - The Classification Of Alkyl Halides, Alcohols, And AminesChapter 3.6 - The Structures Of Alkyl Halides, Alcohols, Ethers, And AminesChapter 3.7 - Noncovalent InteractionsChapter 3.8 - Factors That Affect The Solubility Of Organic CompoundsChapter 3.9 - Rotation Occurs About Carbon-carbon Single BondsChapter 3.11 - Conformers Of CyclohexaneChapter 3.12 - Conformers Of Monosubstituted CyclohexanesChapter 3.13 - Conformers Of Disubstituted CyclohexanesChapter 4 - Isomers: The Arrangement Of Atoms In SpaceChapter 4.1 - Cis-trans Isomers Result From Restricted RotationChapter 4.2 - Designating Geometric Isomers Using The E,z SystemChapter 4.3 - A Chiral Object Has A Nonsuperimposable Mirror ImageChapter 4.4 - An Asymmetric Center Is A Cause Of Chirality In A MoleculeChapter 4.5 - Isomers With One Asymmetric CenterChapter 4.6 - How To Draw EnantiomersChapter 4.7 - Naming Enantiomers By The R,s SystemChapter 4.8 - Chiral Compounds Are Optically ActiveChapter 4.9 - How Specific Rotation Is MeasuredChapter 4.10 - Isomers With More Than One Asymmetric CenterChapter 4.11 - Stereoisomers Of Cyclic CompoundsChapter 4.12 - Meso Compounds Have Asymmetric Centers But Are Optically InactiveChapter 5 - AlkenesChapter 5.1 - The Nomenclature Of AlkenesChapter 5.3 - How Alkenes React • Curved Arrows Show The Flow Of ElectronsChapter 5.4 - Thermodynamics: How Much Product Is Formed?Chapter 5.6 - Calculating Δη° Values To Determine The Relative Stabilities Of AlkenesChapter 5.7 - Kinetics: How Fast Is The Product Formed?Chapter 5.9 - A Reaction Coordinate Diagram Describes The Energy Changes That Take Place During A ReactionChapter 5.10 - CatalysisChapter 6 - The Reaction Of Alkenes And AlkynesChapter 6.1 - The Addition Of A Hydrogen Halide To An AlkeneChapter 6.2 - Carbocation Stability Depends On The Number Of Alkyl Groups Attached To The Positively Charged CarbonChapter 6.3 - Electrphilic Addition Reactions Are RegioselectiveChapter 6.5 - The Addition Of Water To An AlkeneChapter 6.6 - The Stereochemistry Of Alkene ReactionsChapter 6.8 - Enantiomers Can Be Distinguished By Biological MoleculesChapter 6.10 - The Nomenclature Of AlkynesChapter 6.11 - The Structure Of AlkynesChapter 6.13 - The Addition Of A Hydrogen Halide To An AlkyneChapter 6.14 - The Addition Of Water To An AlkyneChapter 6.15 - The Addition Of Hydrogen To An AlkyneChapter 7 - Delocalized Electrons: Their Effect On Stability, Pka, And The Products Of A Reaction • Aromaticity And Electronic Effects: An Introduction To The Reactions Of BenzeneChapter 7.4 - How To Draw Resonance ContributorsChapter 7.5 - The Predicted Stabilities Of Resonance ContributorsChapter 7.6 - Delocalization Energy Is The Additional Stability Delocalized Electrons Give To A CompoundChapter 7.7 - Delocalized Electrons Increase StabilityChapter 7.8 - Delocalized Electrons Affect Pka ValuesChapter 7.9 - Electronic EffectsChapter 7.11 - Reactions Of DienesChapter 7.12 - The Diels-alder Reaction Is A 1,4-addition ReactionChapter 7.15 - Applying The Criteria For AromaticityChapter 7.17 - The Mechanism For Electrophilic Aromatic Substitution ReactionsChapter 8 - Substitution And Elimination Reactions Of Alkyl HalidesChapter 8.1 - The Mechanism Of An Sn2 ReactionChapter 8.2 - Factors That Affect Sn2 ReactionsChapter 8.3 - The Mechanism Of An Sn1 ReactionChapter 8.4 - Factors That Affect Sn1 ReactionsChapter 8.5 - Comparing Sn2 And Sn1 ReactionsChapter 8.6 - Intermolecular Versus Intramolecular ReactionsChapter 8.9 - Relative Reactivities Of Alkyl Halides ReactionsChapter 8.11 - Competition Between Substitution And EliminationChapter 8.12 - Solvent EffectsChapter 8.13 - Substitution Reactions In SynthesisChapter 9 - Reactions Of Alcohols, Ethers, Epoxides, Amines, And ThiolsChapter 9.1 - The Nomenclatur Of AlcoholsChapter 9.2 - Activating An Alcohol For Nucleophilic Substitution By ProtonationChapter 9.4 - Elimination Reactions Of Alcohols: DehydrationChapter 9.5 - Oxidation Of AlcoholsChapter 9.6 - Nomenclature Of EthersChapter 9.8 - Nucleophilic Substitution Reactions Of EpoxidesChapter 9.9 - Using Carbocation Stability To Determine The Carcinogenicity Of An Arene OxideChapter 9.11 - Thiols, Sulfides, And Sulfonium IonsChapter 10 - Determining The Structure Of Organic CompoundsChapter 10.1 - Mass SpectrometryChapter 10.2 - The Mass Spectrum • FragmentationChapter 10.3 - Using The M/z Value Of The Molecular Ion To Calculate The Molecular FormulaChapter 10.4 - Isotopes In Mass SpectrometryChapter 10.5 - High-resolution Mass Spectrometry Can Reveal Molecular FormulasChapter 10.6 - Fragmentation PatternsChapter 10.8 - Spectroscopy And The Electromagnetic SpectrumChapter 10.12 - The Position Of Absorption BandsChapter 10.13 - The Position And Shape Of An Absorption Band Is Affected By Electron Delocalization, Electron Donation And Withdrawal, And Hydrogen BondingChapter 10.14 - The Absence Of Absorption BandsChapter 10.15 - How To Interpret An Infrared SpectrumChapter 10.17 - The Effect Of Conjugation On ΛmaxChapter 10.18 - The Visible Spectrum And ColorChapter 10.19 - Some Uses Of Uv/vis SpectroscopyChapter 10.22 - The Number Of Signals In 1h Nmr SpectrumChapter 10.23 - The Chemical Shift Tells How Far The Signal Is From The Reference SignalChapter 10.24 - The Relative Positions Of 1h Nmr SignalsChapter 10.25 - The Characteristic Values Of Chemical ShiftsChapter 10.26 - The Integration Of Nmr Signals Reveals The Relative Number Of Protons Causing Each SignalChapter 10.27 - The Splitting Of Signals Is Described By The N+1 RuleChapter 10.28 - More Examples Of 1h Nmr SpectraChapter 10.29 - 13c Nmr SpectroscopyChapter 11 - Reactions Of Carboxylic Acids And Carboxylic Acid DerivativesChapter 11.1 - The Nomenclature Of Carboxylic Acids And Carboxylic Acid DerivativesChapter 11.2 - The Structures Of Carboxylic Acids And Carboxylic Acid DerivativesChapter 11.4 - How Carboxylic Acids And Carboxylic Acid Derivatives ReactChapter 11.5 - The Relative Reactivities Of Carboxylic Acids And Carboxylic Acid DerivativesChapter 11.6 - The Reactions Of Acyl ChloridesChapter 11.7 - The Reactions Of EstersChapter 11.8 - Acid-catalyzed Ester Hydrolysis And TransesterificationChapter 11.9 - Hydroxide-ion-promoted Ester HydrolysisChapter 11.10 - Reactions Of Carboxylic AcidsChapter 11.11 - Reactions Of AmidesChapter 11.12 - NitrilesChapter 11.13 - Acid AnhydridesChapter 11.14 - How Chemists Activate Carboxylic AcidsChapter 11.15 - How Cells Activate Carboxylic AcidsChapter 12 - Reactions Of Aldehydes And Ketones • More Reactions Of Carboxylic Acid DerivativesChapter 12.1 - The Nomenclature Of Aldehydes And KetonesChapter 12.2 - The Relative Reactivities Of Carbonyl CompoundsChapter 12.4 - Organometallic CompoundsChapter 12.5 - The Reactions Of Carbonyl Compounds With Grignard ReagentsChapter 12.6 - The Reactions Of Aldehydes And Ketones With Cyanide IonChapter 12.7 - The Reactions Of Carbonyl Compounds With Hydride IonsChapter 12.8 - The Reactions Of Aldehydes And Ketones With AminesChapter 12.9 - The Reactions Of Aldehydes And Ketones With AlcoholsChapter 12.10 - Nucleophilic Addition To Α,β-unsaturated Aldehydes And KetonesChapter 12.11 - Nucleophilic Addition To Α,β-unsaturated Carboxylic Acid DerivativesChapter 13 - Reactions At The Α-carbon Of Carbonyl CompoundsChapter 13.1 - The Aciidity Of An Α-hydrogenChapter 13.2 - Keto-enol TautomersChapter 13.3 - Keto-enol InterconversionChapter 13.4 - Alkylation Of Enolate IonsChapter 13.5 - An Aldol Addition Forms A Β-hydroxyaldehyde Or A Β-hydroxyketoneChapter 13.6 - The Dehydration Of Aldol Addition Products Forms Α,β-unsaturated Aldehydes And KetonesChapter 13.7 - A Crossed Aldol AdditionChapter 13.8 - A Claisen Condensation Forms A Β-keto EsterChapter 13.9 - Co2 Can Be Removed From A Carboxylic Acid That Has A Carbonyl Group At The 3-positionChapter 13.10 - Reactions At The Α-carbon In CellsChapter 14 - RadicalsChapter 14.2 - The Chlorination And Bromination Of AlkanesChapter 14.4 - The Distribution Of Products Depends On Radical StabilityChapter 14.5 - The Stereochemistry Of Radical Substitution ReactionsChapter 14.6 - Formation Of Explosive PeroxidesChapter 14.7 - Radical Reactions Occur In Biological SystemsChapter 15 - Synthetic PolymersChapter 15.2 - Chain-growth PolymersChapter 15.5 - Polymerization Of Dienes • Natural And Synthetic RubberChapter 15.6 - CopolymersChapter 15.8 - Classes Of Step-growth PolymersChapter 15.10 - Biodegradable PolymersChapter 16 - The Organic Chemistry Of CarbohydratesChapter 16.1 - Classifying CarbohydratesChapter 16.2 - The D And L NotationChapter 16.3 - The Configurations Of AldosesChapter 16.4 - The Configurations Of KetosesChapter 16.5 - The Reactions Of Monosaccharides In Basic SolutionsChapter 16.6 - Monosaccharides Form Cyclic HemiacetalsChapter 16.8 - Formation Of GlycosidesChapter 16.9 - DisaccharidesChapter 16.10 - PolysaccharidesChapter 16.11 - Carbohydrates On Cell SurfacesChapter 17 - The Organic Chemistry Of Amino Acids, Peptides, And ProteinsChapter 17.1 - The Nomenclature Of Amino AcidsChapter 17.2 - The Configuration Of Amino AcidsChapter 17.3 - The Acid-base Properties Of Amino AcidsChapter 17.4 - The Isoelectric PointChapter 17.5 - Separating Amino AcidsChapter 17.6 - The Synthesis Of Amino AcidsChapter 17.7 - The Resolution Of Racemic Mixtures Of Amino AcidsChapter 17.8 - Peptide Bonds And Disulfide BondsChapter 17.10 - How To Determine The Primary Structure Of A Polypeptide Or A ProteinChapter 17.12 - Tertiary StructureChapter 17.13 - Quaternary StructureChapter 18 - How Enzymes Catalyze Reactions • The Organic Chemistry Of The VitaminsChapter 18.1 - Enzyme-catalyzed ReactionsChapter 18.2 - An Enzyme-catalyzed Reactions That Involved Two Sequential Sn2 ReactionsChapter 18.3 - An Enzyme-catalyzed Reaction That Is Reminiscent Of Acid-catalyzed Amide And Ester HydrolysisChapter 18.4 - An Enzyme-catalyzed Reaction That Is Reminiscent Of The Base-catalyzed Enediol RearrangementChapter 18.5 - Another Enzyme-catalyzed Reaction That Is Reminiscent Of A Retro-aldol AdditionChapter 18.7 - Niacin: The Vitamin Needed For Many Redox ReactionsChapter 18.8 - Riboflavin: Another Vitamin Used In Redox ReactionsChapter 18.9 - Vitamin B1: The Vitamin Needed For Acyl Group TransferChapter 18.10 - Vitamin H: The Vitamin Needed For Caboxylation Of An Α-carbonChapter 18.11 - Vitamin B6: The Vitamin Needed For Amino Acid TransformationsChapter 18.12 - Vitamin B12: The Vitamin Needed For Certain IsomerizationsChapter 18.13 - Folic Acid: The Vitamin Needed For One-carbon TransferChapter 19 - The Organic Chemistry Of The Metabolic PathwaysChapter 19.4 - The Catabolism Of FatsChapter 19.5 - The Catabolism Of CarbohydratesChapter 19.6 - The Fats Of PyruvateChapter 19.7 - The Catabolism Of ProteinsChapter 19.8 - The Citric Acid CycleChapter 19.9 - Oxidative PhosphorylationChapter 19.10 - AnabolismChapter 19.13 - Amino Acid BiosynthesisChapter 20 - The Organic Chemistry Of LipidsChapter 20.1 - Fatty Acids Are Long-chain Carboxylic AcidsChapter 20.2 - Fats And Oils Are TriglyveridesChapter 20.4 - Phosphoglycerides And SphingolipidsChapter 20.6 - Terpenes Contain Carbon Atoms In Multiples Of FiveChapter 20.7 - How Terpenes Are BiosynthesizedChapter 20.8 - How Nature Synthesizes CholesterolChapter 20.9 - Synthetic SteroidsChapter 21 - The Chemistry Of The Nucleic AcidsChapter 21.1 - Nucleosides And NucleotidesChapter 21.3 - The Secondary Structure Of Dna-the Double HelixChapter 21.4 - Why Dna Does Not Have A 2'-oh GroupChapter 21.5 - The Biosynthesis Of Dna Is Called ReplicationChapter 21.7 - The Biosynthesis Of Rna Is Called TranscriptionChapter 21.9 - The Biosynthesis Of Proteins Is Called TranslationChapter 21.10 - Why Dna Contains Thymine Instead Of UracilChapter 21.12 - How The Base Sequence Of Dna Is Determined

More Editions of This Book

Corresponding editions of this textbook are also available below:

Essential Organic Chemistry: Study Guide & Solutions Manual
6th Edition
ISBN: 9780131498600
EBK ESSENTIAL ORGANIC CHEMISTRY
3rd Edition
ISBN: 8220100659461
Pearson eText for Essential Organic Chemistry -- Instant Access (Pearson+)
3rd Edition
ISBN: 9780137533268
Essential Organic Chemistry (3rd Edition)
3rd Edition
ISBN: 9780321937711
Essential Organic Chemistry Study Guide & Solution Manual, Books a la Carte Edition
3rd Edition
ISBN: 9780134255644
EBK ESSENTIAL ORGANIC CHEMISTRY
3rd Edition
ISBN: 9780100659469
Essential Organic Chemistry
2nd Edition
ISBN: 9780321596956

Related Chemistry Textbooks with Solutions

Still sussing out bartleby
Check out a sample textbook solution.
See a sample solution