NMR SOLOMON Chap13

Information about NMR SOLOMON Chap13

Published on October 15, 2007

Author: Freedom

Source: authorstream.com

Content

Chapter 13 Nuclear Magnetic Resonance Spectroscopy:  Chapter 13 Nuclear Magnetic Resonance Spectroscopy Jo Blackburn Richland College, Dallas, TX Dallas County Community College District ã 2003, Prentice Hall Organic Chemistry, 5th Edition L. G. Wade, Jr. Introduction:  Introduction NMR is the most powerful tool available for organic structure determination. It is used to study a wide variety of nuclei: 1H 13C 15N 19F 31P => Nuclear Spin:  Nuclear Spin A nucleus with an odd atomic number or an odd mass number has a nuclear spin. The spinning charged nucleus generates a magnetic field. External Magnetic Field:  External Magnetic Field When placed in an external field, spinning protons act like bar magnets. => Two Energy States:  Two Energy States The magnetic fields of the spinning nuclei will align either with the external field, or against the field. A photon with the right amount of energy can be absorbed and cause the spinning proton to flip. => E and Magnet Strength:  E and Magnet Strength Energy difference is proportional to the magnetic field strength. E = h =  h B0 2 Gyromagnetic ratio, , is a constant for each nucleus (26,753 s-1gauss-1 for H). In a 14,092 gauss field, a 60 MHz photon is required to flip a proton. Low energy, radio frequency. => Magnetic Shielding:  Magnetic Shielding If all protons absorbed the same amount of energy in a given magnetic field, not much information could be obtained. But protons are surrounded by electrons that shield them from the external field. Circulating electrons create an induced magnetic field that opposes the external magnetic field. => Shielded Protons:  Shielded Protons Magnetic field strength must be increased for a shielded proton to flip at the same frequency. Protons in a Molecule:  Protons in a Molecule Depending on their chemical environment, protons in a molecule are shielded by different amounts. NMR Signals:  NMR Signals The number of signals shows how many different kinds of protons are present. The location of the signals shows how shielded or deshielded the proton is. The intensity of the signal shows the number of protons of that type. Signal splitting shows the number of protons on adjacent atoms. => The NMR Spectrometer:  The NMR Spectrometer => The NMR Graph:  The NMR Graph => Tetramethylsilane:  Tetramethylsilane TMS is added to the sample. Since silicon is less electronegative than carbon, TMS protons are highly shielded. Signal defined as zero. Organic protons absorb downfield (to the left) of the TMS signal. => Chemical Shift:  Chemical Shift Measured in parts per million. Ratio of shift downfield from TMS (Hz) to total spectrometer frequency (Hz). Same value for 60, 100, or 300 MHz machine. Called the delta scale. => Delta Scale:  Delta Scale => Location of Signals:  Location of Signals More electronegative atoms deshield more and give larger shift values. Effect decreases with distance. Additional electronegative atoms cause increase in chemical shift. => Typical Values:  Typical Values => Aromatic Protons, 7-8:  Aromatic Protons, 7-8 => Vinyl Protons, 5-6:  Vinyl Protons, 5-6 => Acetylenic Protons, 2.5:  Acetylenic Protons, 2.5 => Aldehyde Proton, 9-10:  Aldehyde Proton, 9-10 => Electronegative oxygen atom O-H and N-H Signals:  O-H and N-H Signals Chemical shift depends on concentration. Hydrogen bonding in concentrated solutions deshield the protons, so signal is around 3.5 for N-H and 4.5 for O-H. Proton exchanges between the molecules broaden the peak. => Carboxylic Acid Proton, 10+:  Carboxylic Acid Proton, 10+ => Number of Signals:  Number of Signals Equivalent hydrogens have the same chemical shift. => Intensity of Signals:  Intensity of Signals The area under each peak is proportional to the number of protons. Shown by integral trace. How Many Hydrogens?:  How Many Hydrogens? When the molecular formula is known, each integral rise can be assigned to a particular number of hydrogens. Spin-Spin Splitting:  Spin-Spin Splitting Nonequivalent protons on adjacent carbons have magnetic fields that may align with or oppose the external field. This magnetic coupling causes the proton to absorb slightly downfield when the external field is reinforced and slightly upfield when the external field is opposed. All possibilities exist, so signal is split. => 1,1,2-Tribromoethane:  1,1,2-Tribromoethane Nonequivalent protons on adjacent carbons. => Doublet: 1 Adjacent Proton:  Doublet: 1 Adjacent Proton => Triplet: 2 Adjacent Protons:  Triplet: 2 Adjacent Protons => The N + 1 Rule:  The N + 1 Rule If a signal is split by N equivalent protons, it is split into N + 1 peaks. => Range of Magnetic Coupling:  Range of Magnetic Coupling Equivalent protons do not split each other. Protons bonded to the same carbon will split each other only if they are not equivalent. Protons on adjacent carbons normally will couple. Protons separated by four or more bonds will not couple. => Splitting for Ethyl Groups:  Splitting for Ethyl Groups => Splitting for Isopropyl Groups:  Splitting for Isopropyl Groups => Coupling Constants:  Coupling Constants Distance between the peaks of multiplet Measured in Hz Not dependent on strength of the external field Multiplets with the same coupling constants may come from adjacent groups of protons that split each other. => Values for Coupling Constants:  Values for Coupling Constants => Complex Splitting:  Complex Splitting Signals may be split by adjacent protons, different from each other, with different coupling constants. Example: Ha of styrene which is split by an adjacent H trans to it (J = 17 Hz) and an adjacent H cis to it (J = 11 Hz). => Splitting Tree:  Splitting Tree Spectrum for Styrene:  Spectrum for Styrene => Stereochemical Nonequivalence:  Stereochemical Nonequivalence Usually, two protons on the same C are equivalent and do not split each other. If the replacement of each of the protons of a -CH2 group with an imaginary “Z” gives stereoisomers, then the protons are non-equivalent and will split each other. => Some Nonequivalent Protons:  Some Nonequivalent Protons Time Dependence:  Time Dependence Molecules are tumbling relative to the magnetic field, so NMR is an averaged spectrum of all the orientations. Axial and equatorial protons on cyclohexane interconvert so rapidly that they give a single signal. Proton transfers for OH and NH may occur so quickly that the proton is not split by adjacent protons in the molecule. => Hydroxyl Proton:  Hydroxyl Proton Ultrapure samples of ethanol show splitting. Ethanol with a small amount of acidic or basic impurities will not show splitting. N-H Proton:  N-H Proton Moderate rate of exchange. Peak may be broad. Identifying the O-H or N-H Peak:  Identifying the O-H or N-H Peak Chemical shift will depend on concentration and solvent. To verify that a particular peak is due to O-H or N-H, shake the sample with D2O Deuterium will exchange with the O-H or N-H protons. On a second NMR spectrum the peak will be absent, or much less intense. => Carbon-13:  Carbon-13 12C has no magnetic spin. 13C has a magnetic spin, but is only 1% of the carbon in a sample. The gyromagnetic ratio of 13C is one-fourth of that of 1H. Signals are weak, getting lost in noise. Hundreds of spectra are taken, averaged. => Fourier Transform NMR:  Fourier Transform NMR Nuclei in a magnetic field are given a radio-frequency pulse close to their resonance frequency. The nuclei absorb energy and precess (spin) like little tops. A complex signal is produced, then decays as the nuclei lose energy. Free induction decay is converted to spectrum. => Hydrogen and Carbon Chemical Shifts:  Hydrogen and Carbon Chemical Shifts Combined 13C and 1H Spectra:  Combined 13C and 1H Spectra => Differences in 13C Technique:  Differences in 13C Technique Resonance frequency is ~ one-fourth, 15.1 MHz instead of 60 MHz. Peak areas are not proportional to number of carbons. Carbon atoms with more hydrogens absorb more strongly. => Spin-Spin Splitting:  Spin-Spin Splitting It is unlikely that a 13C would be adjacent to another 13C, so splitting by carbon is negligible. 13C will magnetically couple with attached protons and adjacent protons. These complex splitting patterns are difficult to interpret. => Proton Spin Decoupling:  Proton Spin Decoupling To simplify the spectrum, protons are continuously irradiated with “noise,” so they are rapidly flipping. The carbon nuclei see an average of all the possible proton spin states. Thus, each different kind of carbon gives a single, unsplit peak. => Off-Resonance Decoupling:  Off-Resonance Decoupling 13C nuclei are split only by the protons attached directly to them. The N + 1 rule applies: a carbon with N number of protons gives a signal with N + 1 peaks. => Interpreting 13C NMR:  Interpreting 13C NMR The number of different signals indicates the number of different kinds of carbon. The location (chemical shift) indicates the type of functional group. The peak area indicates the numbers of carbons (if integrated). The splitting pattern of off-resonance decoupled spectrum indicates the number of protons attached to the carbon. => Two 13C NMR Spectra:  Two 13C NMR Spectra => MRI:  MRI Magnetic resonance imaging, noninvasive “Nuclear” is omitted because of public’s fear that it would be radioactive. Only protons in one plane can be in resonance at one time. Computer puts together “slices” to get 3D. Tumors readily detected. => End of Chapter 13:  End of Chapter 13

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