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The Spectrometric Identification of Organic Compounds, Eighth Edition
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  • Wiley

More About This Title The Spectrometric Identification of Organic Compounds, Eighth Edition

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First published over 40 years ago, this was the first text on the identification of organic compounds using spectroscopy. This text is now considered to be a classic. This text presents a unified approach to the structure determination of organic compounds based largely on mass spectrometry, infrared (IR) spectroscopy, and multinuclear and multidimensional nuclear magnetic resonance (NMR) spectroscopy. The key strength of this text is the extensive set of practice and real-data problems (in Chapters 7 and 8). Even professional chemists use these spectra as reference data. Spectrometric Identification of Organic Compounds is written by and for organic chemists, and emphasizes the synergistic effect resulting from the interplay of the spectra. This book is characterized by its problem-solving approach with extensive reference charts and tables.

The 8th edition of this text maintains its student-friendly writing style - wording throughout has been updated for consistency and to be more reflective of modern usage and methods. Chapter 3 on proton NMR spectroscopy has been overhauled and updated. Also, new information on polymers and phosphorus functional groups has been added to Chapter 2 on IR spectroscopy.

  • English

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Robert M. Silverstein, PhD was as born in Baltimore, MD, and moved to Staten Island at a young age. He received his bachelor's degree from the University of Pennsylvania in 1937 and his masters' degree from New York University in 1941. He served with the U.S. Army during World War II. He then earned his doctorate from New York University.

Francis X. Webster is the author of Spectrometric Identification of Organic Compounds, 8th Edition, published by Wiley.

David J. Kiemle is the author of Spectrometric Identification of Organic Compounds, 8th Edition, published by Wiley.

David L. Bryce is the author of Spectrometric Identification of Organic Compounds, 8th Edition, published by Wiley.

  • English

English

CHAPTER 1 MASS SPECTROMETRY 1

1.1 Introduction 1

1.2 Instrumentation 2

1.3 Ionization Methods 3

1.4 Mass Analyzers 8

1.5 Interpretation of EI Mass Spectra 12

1.6 Mass Spectra of Some Chemical Classes 18

References 37

Student Exercises 37

Appendices 46

A Formula Masses (FM) for Various Combinations of Carbon, Hydrogen, Nitrogen, and Oxygen 46

B Common Fragment Ions 67

C Common Fragments Lost 69

CHAPTER 2 INFRARED SPECTROSCOPY 71

2.1 Introduction 71

2.2 Theory 71

2.3 Instrumentation 76

2.4 Sample Handling 77

2.5 Interpretation of Spectra 78

2.6 Characteristic Group Absorptions of Organic Molecules 81

References 108

Student Exercises 108

Appendices 118

A Transparent Regions of Solvents and Mulling Oils 118

B Characteristic Group Absorptions 119

C Absorptions for Alkenes 124

D Absorptions for Phosphorus Compounds 125

E Absorptions for Heteroaromatics 125

CHAPTER 3 PROTON (1H) MAGNETIC RESONANCE SPECTROSCOPY 126

3.1 Introduction 126

3.2 Theory 126

3.3 Instrumentation and Sample Handling 129

3.4 Chemical Shift 132

3.5 Spin-Spin Coupling, Multiplets, and Spin Systems 137

3.6 Protons on Oxygen, Nitrogen, and Sulfur Atoms:Exchangeable Protons 144

3.7 Coupling of Protons to Other Important Nuclei (19F, D (2H), 31P, 29Si, and 13C) 149

3.8 Chemical Equivalence 150

3.9 Magnetic Equivalence 154

3.10 AMX, ABX, and ABC Rigid Systems with Three Coupling Constants 155

3.11 Weakly and Strongly Coupled Systems: Virtual Coupling 156

3.12 Chirality 158

3.13 Magnitude of Vicinal and Geminal Coupling Constants 160

3.14 Long-Range Coupling 162

3.15 Selective Spin Decoupling: Double Resonance 162

3.16 Nuclear Overhauser Effect 162

3.17 Conclusion 163

References 164

Student Exercises 164

Appendices 175

A Chart A.1: Chemical Shifts of Protons on a Carbon Atom Adjacent (𝛼 Position) to a Functional Group in Aliphatic Compounds (M–Y) 175

Chart A.2: Chemical Shifts of Protons on a Carbon Atom Once Removed (𝛽 Position) from a Functional Group in Aliphatic Compounds (M–C–Y) 177

B Effect on Chemical Shifts by Two or Three Directly Attached Functional Groups 178

C Chemical Shifts in Alicyclic and Heterocyclic Rings 180

D Chemical Shifts in Unsaturated and Aromatic Systems 181

Chart D.1: Chemical Shifts of Protons on Monosubstituted Benzene Rings 183

E Protons Subject to Hydrogen-Bonding Effects (Protons on Heteroatoms) 184

F Proton Spin-Spin Coupling Constants 185

G Chemical Shifts and Multiplicities of Residual Protons in Commercially Available Deuterated Solvents 187

H Chemical Shifts of Common Laboratory Solvents as Trace Impurities 188

I Proton NMR Chemical Shifts of Amino Acids in D2O 190

CHAPTER 4 CARBON-13 NMR SPECTROSCOPY 191

4.1 Introduction 191

4.2 Theory 191

4.3 Interpretation of a Simple 13C NMR Spectrum: Diethyl Phthalate 198

4.4 Quantitative 13C Analysis 198

4.5 Chemical Equivalence 200

4.6 DEPT 200

4.7 Chemical Classes and Chemical Shifts 203

4.7.1 Alkanes 204

4.7.1.1 Linear and Branched Alkanes 204

4.7.1.2 Effect of Substituents on Alkanes 205

4.7.1.3 Cycloalkanes and Saturated Heterocyclics 205

4.7.2 Alkenes 206

4.7.3 Alkynes 208

4.7.4 Aromatic Compounds 208

4.7.5 Heteroaromatic Compounds 209

4.7.6 Alcohols 209

4.7.7 Ethers, Acetals, and Epoxides 209

4.7.8 Halides 211

4.7.9 Amines 211

4.7.10 Thiols, Sulfides, and Disulfides 211

4.7.11 Functional Groups Containing Carbon 211

4.7.11.1 Ketones and Aldehydes 212

4.7.11.2 Carboxylic Acids, Esters, Chlorides, Anhydrides, Amides, and Nitriles 214

4.7.11.3 Oximes 214

References 214

Student Exercises 214

Appendices 225

A The 13C Chemical Shifts, Coupling Constants, and Peak Multiplicities of Common Deuterated NMR Solvents 225

B 13C Chemical Shifts of Common Laboratory Solvents as Trace Impurities in Selected Deuterated NMR Solvents 226

C 13C Chemical Shift Ranges for Chemical Classes 227

D 13C Chemical Shifts (ppm) for Several Natural Products 229

CHAPTER 5 TWO-DIMENSIONAL NMR SPECTROSCOPY 230

5.1 Introduction 230

5.2 Theory 231

5.3 Correlation Spectroscopy 233

5.3.1 1H-1H Correlation: COSY 235

5.4 Ipsenol: 1H-1H COSY 235

5.4.1 Ipsenol: Double Quantum Filtered 1H-1H COSY 238

5.4.2 Carbon Detected 13C-1H COSY: HETCOR 238

5.4.3 Proton Detected 1H-13C COSY: HMQC 239

5.4.4 Ipsenol: HETCOR and HMQC 239

5.4.5 Ipsenol: Proton-Detected, Long-Range 1H-13C Heteronuclear Correlation: HMBC 241

5.5 Caryophyllene Oxide 243

5.5.1 Caryophyllene Oxide: DQF-COSY 243

5.5.2 Caryophyllene Oxide: HMQC 243

5.5.3 Caryophyllene Oxide: HMBC 247

5.6 13C-13C Correlations: INADEQUATE 249

5.6.1 INADEQUATE: Caryophyllene Oxide 251

5.7 Lactose 251

5.7.1 DQF-COSY: Lactose 251

5.7.2 HMQC: Lactose 254

5.7.3 HMBC: Lactose 254

5.8 Relayed Coherence Transfer: TOCSY 254

5.8.1 2D TOCSY: Lactose 254

5.8.2 1D TOCSY: Lactose 257

5.9 HMQC-TOCSY 259

5.9.1 HMQC-TOCSY: Lactose 259

5.10 ROESY 259

5.10.1 ROESY: Lactose 259

5.11 VGSE 262

5.11.1 COSY: VGSE 262

5.11.2 TOCSY: VGSE 262

5.11.3 HMQC: VGSE 262

5.11.4 HMBC: VGSE 264

5.11.5 ROESY: VGSE 265

5.12 Pulsed Field Gradient NMR 265

References 268

Student Exercises 268

CHAPTER 6 MULTINUCLEAR MAGNETIC RESONANCE SPECTROSCOPY 298

6.1 Introduction and General Considerations 298

6.2 15N Nuclear Magnetic Resonance 299

6.3 19F Nuclear Magnetic Resonance 306

6.4 29Si Nuclear Magnetic Resonance 309

6.5 31P Nuclear Magnetic Resonance 312

6.6 Conclusions 315

References 315

Student Exercises 315

Appendix 320

A Properties of Magnetically Active Nuclei 320

CHAPTER 7 SOLVED PROBLEMS 325

7.1 Introduction 325

Problem 7.1 Discussion 329

Problem 7.2 Discussion 333

Problem 7.3 Discussion 337

Problem 7.4 Discussion 344

Problem 7.5 Discussion 350

Problem 7.6 Discussion 356

Student Exercises 357

CHAPTER 8 ASSIGNED PROBLEMS 364

8.1 Introduction 364

INDEX 453

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