13-1 Organic Chemistry William H. Brown Christopher S. Foote Brent L. Iverson William H. Brown Christopher S. Foote Brent L. Iverson
13-2 Nuclear Magnetic Resonance Chapter 13
13-3 Molecular Spectroscopy Nuclear magnetic resonance (NMR) spectroscopy: Nuclear magnetic resonance (NMR) spectroscopy: a spectroscopic technique that gives us information about the number and types of atoms in a molecule, for example, about the number and types of hydrogen atoms using 1 H-NMR spectroscopy carbon atoms using 13 C-NMR spectroscopy phosphorus atoms using 31 P-NMR spectroscopy
13-4 Nuclear Spin States An electron has a spin quantum number of 1/2 with allowed values of +1/2 and -1/2 this spinning charge creates an associated magnetic field in effect, an electron behaves as if it is a tiny bar magnet and has what is called a magnetic moment The same effect holds for certain atomic nuclei any atomic nucleus that has an odd mass number, an odd atomic number, or both also has a spin and a resulting nuclear magnetic moment the allowed nuclear spin states are determined by the spin quantum number, I, of the nucleus
13-5 Nuclear Spin States I2I + 1a nucleus with spin quantum number I has 2I + 1 spin states; if I = 1/2, there are two allowed spin states Table 13.1 gives the spin quantum numbers and allowed nuclear spin states for selected isotopes of elements common to organic compounds
13-6 Nuclear Spins in B 0 within a collection of 1 H and 13 C atoms, nuclear spins are completely random in orientation when placed in a strong external magnetic field of strength B 0, however, interaction between nuclear spins and the applied magnetic field is quantized, with the result that only certain orientations of nuclear magnetic moments are allowed
13-7 Nuclear Spins in B 0 for 1 H and 13 C, only two orientations are allowed
13-8 Nuclear Spins in B 0 In an applied field strength of 7.05T, which is readily available with present-day superconducting electromagnets, the difference in energy between nuclear spin states for 1 H is approximately J ( cal)/mol, which corresponds to electromagnetic radiation of 300 MHz (300,000,000 Hz) 13 C is approximately J ( cal)/mol, which corresponds to electromagnetic radiation of 75MHz (75,000,000 Hz)
13-9 Nuclear Spin in B 0 the energy difference between allowed spin states increases linearly with applied field strength values shown here are for 1 H nuclei
13-10 Nuclear Magnetic Resonance when nuclei with a spin quantum number of 1/2 are placed in an applied field, a small majority of nuclear spins are aligned with the applied field in the lower energy state the nucleus begins to precess and traces out a cone- shaped surface, in much the same way a spinning top or gyroscope traces out a cone-shaped surface as it precesses in the earth’s gravitational field we express the rate of precession as a frequency in hertz
13-11 Nuclear Magnetic Resonance If the precessing nucleus is irradiated with electromagnetic radiation of the same frequency as the rate of precession, the two frequencies couple, energy is absorbed, and the nuclear spin is flipped from spin state +1/2 (with the applied field) to -1/2 (against the applied field)
13-12 Nuclear Magnetic Resonance Figure 13.3 the origin of nuclear magnetic “resonance
13-13 Nuclear Magnetic Resonance Resonance: Resonance: in NMR spectroscopy, resonance is the absorption of electromagnetic radiation by a precessing nucleus and the resulting “flip” of its nuclear spin from a lower energy state to a higher energy state The instrument used to detect this coupling of precession frequency and electromagnetic radiation records it as a signal signal:signal: a recording in an NMR spectrum of a nuclear magnetic resonance
13-14 Nuclear Magnetic Resonance if we were dealing with 1 H nuclei isolated from all other atoms and electrons, any combination of applied field and radiation that produces a signal for one 1 H would produce a signal for all 1 H. The same is true of 13 C nuclei but hydrogens in organic molecules are not isolated from all other atoms; they are surrounded by electrons, which are caused to circulate by the presence of the applied field diamagneticcurrent diamagnetic shieldingthe circulation of electrons around a nucleus in an applied field is called diamagnetic current and the nuclear shielding resulting from it is called diamagnetic shielding
13-15 Nuclear Magnetic Resonance the difference in resonance frequencies among the various hydrogen nuclei within a molecule due to shielding/deshielding is generally very small the difference in resonance frequencies for hydrogens in CH 3 Cl compared to CH 3 F under an applied field of 7.05T is only 360 Hz, which is 1.2 parts per million (ppm) compared with the irradiating frequency
13-16 Nuclear Magnetic Resonance signals are measured relative to the signal of the reference compound tetramethylsilane (TMS) for a 1 H-NMR spectrum, signals are reported by their shift from the 12 H signal in TMS for a 13 C-NMR spectrum, signals are reported by their shift from the 4 C signal in TMS Chemical shift ( ):Chemical shift ( ): the shift in ppm of an NMR signal from the signal of TMS
13-17 NMR Spectrometer
13-18 Essentials of an NMR spectrometer are a powerful magnet, a radio-frequency generator, and a radio-frequency detector The sample is dissolved in a solvent, most commonly CDCl 3 or D 2 O, and placed in a sample tube which is then suspended in the magnetic field and set spinning Using a Fourier transform NMR (FT-NMR) spectrometer, a spectrum can be recorded in about 2 seconds
13-19 NMR Spectrum 1 H-NMR spectrum of methyl acetate Downfield:Downfield: the shift of an NMR signal to the left on the chart paper Upfield:Upfield: the shift of an NMR signal to the right on the chart paper
13-20 Equivalent Hydrogens Equivalent hydrogens: Equivalent hydrogens: have the same chemical environment a molecule with 1 set of equivalent hydrogens gives 1 NMR signal
13-21 Equivalent Hydrogens a molecule with 2 or more sets of equivalent hydrogens gives a different NMR signal for each set
13-22 Signal Areas Relative areas of signals are proportional to the number of H giving rise to each signal Modern NMR spectrometers electronically integrate and record the relative area of each signal
13-23 ChemicalShifts 1 H-NMR
13-24 Chemical Shift - 1 H-NMR
13-25 Chemical Shift Depends on (1) electronegativity of nearby atoms, (2) the hybridization of adjacent atoms, and (3) diamagnetic effects from adjacent pi bonds Electronegativity
13-26 Chemical Shift Hybridization of adjacent atoms
13-27 Chemical Shift Diamagnetic effects of pi bonds a carbon-carbon triple bond shields an acetylenic hydrogen and shifts its signal upfield (to the right) to a smaller value a carbon-carbon double bond deshields vinylic hydrogens and shifts their signal downfield (to the left) to a larger value
13-28 Chemical Shift magnetic induction in the pi bonds of a carbon-carbon triple bond (Fig 13.9)
13-29 Chemical Shift magnetic induction in the pi bond of a carbon-carbon double bond (Fig 13.10)
13-30 Chemical Shift magnetic induction of the pi electrons in an aromatic ring (Fig )
13-31 Signal Splitting; the (n + 1) Rule Peak: Peak: the units into which an NMR signal is split; doublet, triplet, quartet, etc. Signal splitting: Signal splitting: splitting of an NMR signal into a set of peaks by the influence of neighboring nonequivalent hydrogens (n + 1) rule: (n + 1) rule: if a hydrogen has n hydrogens nonequivalent to it but equivalent among themselves on the same or adjacent atom(s), its 1 H-NMR signal is split into (n + 1) peaks
13-32 Signal Splitting (n + 1) 1 H-NMR spectrum of 1,1-dichloroethane
13-33 Signal Splitting (n + 1) Problem Problem: predict the number of 1 H-NMR signals and the splitting pattern of each
13-34 Origins of Signal Splitting Signal coupling: Signal coupling: an interaction in which the nuclear spins of adjacent atoms influence each other and lead to the splitting of NMR signals Coupling constant (J): Coupling constant (J): the separation on an NMR spectrum (in hertz) between adjacent peaks in a multiplet; a quantitative measure of the influence of the spin-spin coupling with adjacent nuclei
13-35 Origins of Signal Splitting
13-36 because splitting patterns from spectra taken at 300 MHz and higher are often difficult to see, it is common to retrace certain signals in expanded form 1 H-NMR spectrum of 3-pentanone; scale expansion shows the triplet quartet pattern more clearly
13-37 Coupling Constants Coupling constant (J): Coupling constant (J): the distance between peaks in a split signal, expressed in hertz the value is a quantitative measure of the magnetic interaction of nuclei whose spins are coupled
13-38 Origins of Signal Splitting
13-39 Signal Splitting Pascal’s Triangle as illustrated by the highlighted entries, each entry is the sum of the values immediately above it to the left and the right
13-40 Physical Basis for (n + 1) Rule Coupling of nuclear spins is mediated through intervening bonds H atoms with more than three bonds between them generally do not exhibit noticeable coupling for H atoms three bonds apart, the coupling is referred to as vicinal coupling
13-41 Coupling Constants an important factor in vicinal coupling is the angle between the C-H sigma bonds and whether or not it is fixed coupling is a maximum when is 0° and 180°; it is a minimum when is 90°
13-42 More Complex Splitting Patterns thus far, we have concentrated on spin-spin coupling with only one other nonequivalent set of H atoms more complex splittings arise when a set of H atoms couples to more than one set H atoms a tree diagram shows that when H b is adjacent to nonequivalent H a on one side and H c on the other, the resulting coupling gives rise to a doublet of doublets
13-43 More Complex Splitting Patterns if H c is a set of two equivalent H, then the observed splitting is a doublet of triplets
13-44 More Complex Splitting Patterns because the angle between C-H bond determines the extent of coupling, bond rotation is a key parameter in molecules with relatively free rotation about C-C sigma bonds, H atoms bonded to the same carbon in CH 3 and CH 2 groups generally are equivalent if there is restricted rotation, as in alkenes and cyclic structures, H atoms bonded to the same carbon may not be equivalent nonequivalent H on the same carbon will couple and cause signal splitting geminal couplingthis type of coupling is called geminal coupling
13-45 More Complex Splitting Patterns in ethyl propenoate, an unsymmetrical terminal alkene, the three vinylic hydrogens are nonequivalent
13-46 More Complex Splitting Patterns a tree diagram for the complex coupling of the three vinylic hydrogens in ethyl propenoate
13-47 More Complex Splitting Patterns cyclic structures often have restricted rotation about their C-C bonds and have constrained conformations as a result, two H atoms on a CH 2 group can be nonequivalent, leading to complex splitting
13-48 More Complex Splitting Patterns a tree diagram for the complex coupling in 2-methyl-2- vinyloxirane
13-49 More Complex Splitting Patterns Complex coupling in flexible molecules coupling in molecules with unrestricted bond rotation often gives only m + n + I peaks that is, the number of peaks for a signal is the number of adjacent hydrogens + 1, no matter how many different sets of equivalent H atoms that represents the explanation is that bond rotation averages the coupling constants throughout molecules with freely rotation bonds and tends to make them similar; for example in the 6- to 8-Hz range for H atoms on freely rotating sp 3 hybridized C atoms
13-50 More Complex Splitting Patterns simplification of signal splitting occurs when coupling constants are the same
13-51 More Complex Splitting Patterns an example of peak overlap occurs in the spectrum of 1-chloro-3-iodopropane the central CH 2 has the possibility for 9 peaks (a triplet of triplets) but because J ab and J bc are so similar, only = 5 peaks are distinguishable
13-52 Stereochemistry & Topicity Depending on the symmetry of a molecule, otherwise equivalent hydrogens may be homotopic enantiotopic diastereotopic The simplest way to visualize topicity is to substitute an atom or group by an isotope; is the resulting compound the same as its mirror image different from its mirror image are diastereomers possible
13-53 Stereochemistry & Topicity Homotopic atoms or groups homotopic atoms or groups have identical chemical shifts under all conditions Achiral H C H Cl Cl H C D Cl Cl Dichloro- methane (achiral) Substitution does not produce a stereocenter; therefore hydrogens are homotopic. Substitute one H by D Achiral H C H Cl Cl H C D Cl Cl Dichloro- methane (achiral) Substitution does not produce a stereocenter; therefore hydrogens are homotopic. Substitute one H by D
13-54 Stereochemistry & Topicity Enantiotopic groups enantiotopic atoms or groups have identical chemical shifts in achiral environments they have different chemical shifts in chiral environments Chiral H C H Cl F H C D Cl F Chlorofluoro- methane (achiral) Substitute one H by D Substitution produces a stereocenter; therefore, hydrogens are enantiotopic. Both hydrogens are prochiral; one is pro-R-chiral, the other is pro-S-chiral. Chiral H C H Cl F H C D Cl F Chlorofluoro- methane (achiral) Substitute one H by D Substitution produces a stereocenter; therefore, hydrogens are enantiotopic. Both hydrogens are prochiral; one is pro-R-chiral, the other is pro-S-chiral.
13-55 Stereochemistry & Topicity Diastereotopic groups H atoms on C-3 of 2-butanol are diastereotopic substitution by deuterium creates a chiral center because there is already a chiral center in the molecule, diastereomers are now possible diastereotopic hydrogens have different chemical shifts under all conditions
13-56 Stereochemistry & Topicity The methyl groups on carbon 3 of 3-methyl-2- butanol are diastereotopic if a methyl hydrogen of carbon 4 is substituted by deuterium, a new chiral center is created because there is already one chiral center, diastereomers are now possible protons of the methyl groups on carbon 3 have different chemical shifts OH 3-Methyl-2-butanol
13-57 Stereochemistry and Topicity 1 H-NMR spectrum of 3-methyl-2-butanol the methyl groups on carbon 3 are diastereotopic and appear as two doublets
C-NMR Spectroscopy Each nonequivalent 13 C gives a different signal a 13 C signal is split by the 1 H bonded to it according to the (n + 1) rule coupling constants of Hz are common, which means that there is often significant overlap between signals, and splitting patterns can be very difficult to determine The most common mode of operation of a 13 C- NMR spectrometer is a hydrogen-decoupled mode
C-NMR Spectroscopy In a hydrogen-decoupled mode, a sample is irradiated with two different radio frequencies one to excite all 13 C nuclei a second broad spectrum of frequencies to cause all hydrogens in the molecule to undergo rapid transitions between their nuclear spin states On the time scale of a 13 C-NMR spectrum, each hydrogen is in an average or effectively constant nuclear spin state, with the result that 1 H- 13 C spin-spin interactions are not observed; they are decoupled
C-NMR Spectroscopy hydrogen-decoupled 13 C-NMR spectrum of 1- bromobutane
13-61 Chemical Shift - 13 C-NMR
13-62
13-63 The DEPT Method In the hydrogen-decoupled mode, information on spin-spin coupling between 13 C and hydrogens bonded to it is lost The DEPT method is an instrumental mode that provides a way to acquire this information Distortionless Enhancement by Polarization Transfer DEPT):Distortionless Enhancement by Polarization Transfer (DEPT): an NMR technique for distinguishing among 13 C signals for CH 3, CH 2, CH, and quaternary carbons
13-64 The DEPT Method The DEPT methods uses a complex series of pulses in both the 1 H and 13 C ranges, with the result that CH 3, CH 2, and CH signals exhibit different phases; signals for CH 3 and CH carbons are recorded as positive signals signals for CH 2 carbons are recorded as negative signals quaternary carbons give no signal in the DEPT method
13-65 Isopentyl acetate 13C-NMR: (a) proton decoupled and (b) DEPT
13-66 Interpreting NMR Spectra Alkanes 1 H-NMR signals appear in the range of C-NMR signals appear in the considerably wider range of Alkenes 1 H-NMR signals appear in the range H-NMR coupling constants are generally larger for trans vinylic hydrogens (J= Hz) compared with cis vinylic hydrogens (J= 5-10 Hz) 13 C-NMR signals for sp 2 hybridized carbons appear in the range , which is downfield from the signals of sp 3 hybridized carbons
13-67 Interpreting NMR Spectra 1 H-NMR spectrum of vinyl acetate (Fig 13.33)
13-68 Interpreting NMR Spectra Alcohols 1 H-NMR O-H chemical shifts often appears in the range , but may be as low as H-NMR chemical shifts of hydrogens on the carbon bearing the -OH group are deshielded by the electron- withdrawing inductive effect of the oxygen and appear in the range Ethers a distinctive feature in the 1 H-MNR spectra of ethers is the chemical shift, , of hydrogens on carbon attached to the ether oxygen
13-69 Interpreting NMR Spectra 1 H-NMR spectrum of 1-propanol (Fig )
13-70 Interpreting NMR Spectra Aldehydes and ketones 1 H-NMR: aldehyde hydrogens appear at H-NMR: -hydrogens of aldehydes and ketones appear at C-NMR: carbonyl carbons appear at Amines 1 H-NMR: amine hydrogens appear at depending on conditions
13-71 Interpreting NMR Spectra Carboxylic acids 1 H-NMR: carboxyl hydrogens appear at 10-13, lower than most any other hydrogens 13 C-NMR: carboxyl carbons in acids and esters appear at
13-72 Interpreting NMR Spectra Spectral Problem 1; molecular formula C 5 H 10 O
13-73 Interpreting NMR Spectra Spectral Problem 2; molecular formula C 7 H 14 O
13-74 Nuclear Magnetic Resonance End Chapter 13