1 Exercises for Chapters 6, 7, 8 & 9 The more difficult and challenging problems are marked with an asterisk, * Chapter 6: Product operators E6-1 Using the standard rotations from section 6.1.4, express the following rotations in terms of sines and cosines: exp exp exp exp exp exp exp exp exp exp exp exp -( ) ( ) -( ) -( ) ( ) - -( ) ( ) -( ) ( ) -( ) ( ) ( ) -( ) -( ) i I I i I i I I i I i I I i I i I I i I i I I i I i I I i I x y x z y z y z y y x y x x x x z x 1 2 1 2 Express all of the above transformations in the shorthand notation of section 6.1.5. E6-2. Repeat the calculation in section 6.1.6 for a spin echo with the 180° pulse about the y-axis. You should find that the magnetization refocuses onto the ­y axis. E6-3. Assuming that magnetization along the y-axis gives rise to an absorption mode lineshape, draw sketches of the spectra which arise from the following operators I1y I2x 2I1yI2z 2I1zI2x E6-4. Describe the following terms in words: I1y I2z 2I1yI2z 2I1xI2x E6-5. Give the outcome of the following rotations I I I I I I I I I x t I x z I I x z I x tI tI x J tI I z y J tI I y y y y z z z z z z 1 1 2 2 1 2 1 1 2 1 2 2 1 1 1 2 2 1 1 2 2 12 1 2 12 1 2 2 2 2 p - - ( ) +( ) - Describe the outcome in words in each case. E6-6. Consider the spin echo sequence ­ ­ 180°(x, to spin 1 and spin 2) ­ ­ applied to a two-spin system. Starting with magnetization along y, represented by I1y, show that overall effect of the sequence is 2 I J I J I Iy y x z1 12 1 12 1 22 2 2spin echo - ( ) + ( )cos sin You should ignore the effect of offsets, which are refocused, are just consider evolution due to coupling. Is your result consistent with the idea that this echo sequence is equivalent to ­ 2 ­ 180°(x, to spin 1 and spin 2) [This calculation is rather more complex than that in section 6.4.1. You will need the identities cos cos sin sin cos sin2 2 22 2 = - =and ] E6-7. For a two-spin system, what delay, , in a spin echo sequence would you use to achieve the following overall transformations (do not worry about signs)? [cos /4 = sin /4 = 1/2] I I I I I I I I I I I I y z x z x x x x y z x x 2 1 2 1 2 2 1 1 2 1 1 2 1 2 1 1 2 2 2 ( ) + ( ) - E6-8. Confirm by a calculation that spin echo sequence c shown on page 6­11 does not refocus the evolution of the offset of spin 1. [Start with a state I1x or I1y; you may ignore the evolution due to coupling]. *E6-9. Express 2 1 2I Ix y in terms of raising and lowering operators: see section 6.5.2. Take the zero-quantum part of your expression and then re-write this in terms of Cartesian operators using the procedure shown in section 6.5.2. E6-10. Consider three coupled spins in which J23 > J12. Following section 6.6, draw a sketch of the doublet and doublets expected for the multiplet on spin 2 and label each line with the spin states of the coupled spins, 1 and 3. Lable the splittings, too. Assuming that magnetization along x gives an absorption mode lineshape, sketch the spectra from the following operators: I I I I I I I Ix z x y z z x z2 1 2 2 3 1 2 32 2 4 E6-11. Complete the following rotations. 3 I I I I I I I I x tI tI tI y z I I I x z z I I I z x J tI I z z z y y y y y y z z 2 1 2 2 1 2 3 2 1 2 2 1 1 2 2 3 3 1 2 3 1 2 3 12 1 2 2 2 2 ( ) + +( ) ( ) + +( ) 22 4 1 2 2 1 2 3 2 1 2 2 23 2 3 23 2 3 12 1 2 13 1 3 I I I I I I z x J tI I z y z J tI I x J tI I tJ I I z z z z z z z z Chapter 7: Two-dimensional NMR E7-1. Sketch the COSY spectra you would expect from the following arrangements of spins. In the diagrams, a line represents a coupling. Assume that the spins have well separated shifts; do not concern yourself with the details of the multiplet structures of the cross- and diagonal-peaks. A B C A B C A B C E7-2. Sketch labelled two-dimensional spectra which have peaks arising from the following transfer processes frequencies in F1 / Hz frequencies in F2 / Hz a 30 Transferred to 30 b 30 and 60 transferred to 30 c 60 transferred to 30 and 60 d 30 transferred to 20, 30 and 60 e 30 and 60 transferred to 30 and 60 E7-3. What would the diagonal-peak multiplet of a COSY spectrum of two spins look like if we assigned the absorption mode lineshape in F2 to magnetization along x and the absorption mode lineshape in F1 to sine modulated data in t1? What would the cross-peak multiplet look like with these assignments? E7-4. The smallest coupling that will gives rise to a discernible cross-peak in a COSY spectra depends on both the linewidth and the signal-to-noise ratio of the spectrum. Explain this observation. 4 *E7-5. Complete the analysis of the DQF COSY spectrum by showing in detail that both the cross and diagonal-peak multiplets have the same lineshape and are in anti-phase in both dimensions. Start from the expression in the middle of page 7­10, section 7.4.21. [You will need the identity cos sin sin sinA B B A B A= +( ) + -( )[ ]1 2 ]. *E7-6. Consider the COSY spectrum for a three-spin system. Start with magnetization just on spin 1. The effect of the first pulse is I Iz I I I y x x x 1 2 1 1 2 3( ) + +( ) - Then, only the offset of spin 1 has an effect - - +I t I t Iy t I y x z 1 1 1 1 1 1 1 1 1 1 cos sin Only the term in I1x leads to cross- and diagonal peaks, so consider this term only from now on. First allow it to evolve under the coupling to spin 2 and then the coupling to spin 3 sin1 1 1 2 212 1 1 2 13 1 1 3 t I x J t I I J t I Iz z z z Then, consider the effect of a 90°(x) pulse applied to all three spins. After this pulse, you should find one term which represents a diagonal-peak multiplet, one which represents a cross-peak multiplet between spin 1 and spin 2, and one which represents a cross-peak multiplet between spin 1 and spin 3. What does the fourth term represent? [More difficult] Determine the form of the cross-peak multiplets, using the approach adopted in section 6.4.1. Sketch the multiplets for the case J12 J23 > J13. [You will need the identity sin sin cos cosA B A B A B= +( ) - -( )[ ]1 2 ] *E7-7. The pulse sequence for two-dimensional TOCSY (total correlation spectroscopy) is shown below t1 isotropic mixing t2 The mixing time, of length , is a period of isotropic mixing. This is a multiple- pulse sequence which results in the transfer of in-phase magnetization from one spin to another. In a two spin system the mixing goes as follows: I J I J Ix x x1 2 12 1 2 12 2 isotropic mixing for time +cos sin We can assume that all terms other than I1x do not survive the isotropic mixing sequence, and so can be ignored. Predict the form of the two-dimensional TOCSY spectrum for a two-spin system. What is the value of which gives the strongest cross peaks? For this optimum value of , what happens to the diagonal peaks? Can you think of any 5 advantages that TOCSY might have over COSY? E7-8. Repeat the analysis for the HMQC experiment , section 7.4.3.1, with the phase of the first spin-2 (carbon-13) pulse set to ­x rather than +x. Confirm that the observable signals present at the end of the sequence do indeed change sign. E7-9. Why must the phase of the second spin-1 (proton) 90° pulse in the HSQC sequence, section 7.4.3.2, be y rather than x? E7-10. Below is shown the pulse sequence for the HETCOR (heteronuclear correlation) experiment 1 H 13 C t1 A C t2 2 2 2 2 B This sequence is closely related to HSQC, but differs in that the signal is observed on carbon-13, rather than being transferred back to proton for observation. Like HSQC and HMQC the resulting spectrum shows cross peaks whose co-ordinates are the shifts of directly attached carbon-13 proton pairs. However, in contrast to these sequences, in HETCOR the proton shift is in F1 and the carbon-13 shift is in F2 . In the early days of two-dimensional NMR this was a popular sequence for shift correlation as it is less demanding of the spectrometer; there are no strong signals from protons not coupled to carbon-13 to suppress. We shall assume that spin 1 is proton, and spin 2 is carbon-13. During period A, t1, the offset of spin 1 evolves but the coupling between spins 1 and 2 is refocused by the centrally placed 180° pulse. During period B the coupling evolves, but the offset is refocused. The optimum value for the time is 1/(2J12), as this leads to complete conversion into anti-phase. The two 90° pulses transfer the anti-phase magnetization to spin 2. During period C the anti-phase magnetization rephases (the offset is refocused) and if is 1/(2J12) the signal is purely in-phase at the start of t2. Make an informal analysis of this sequence, along the lines of that given in section 7.4.3.2, and hence predict the form of the spectrum. In the first instance assume that is set to its optimum value. Then, make the analysis slightly more complex and show that for an arbitrary value of the signal intensity goes as sin2 J12. Does altering the phase of the second spin-1 (proton) 90° pulse from x to y make any difference to the spectrum? [Harder] What happens to carbon-13 magnetization, I2z, present at the beginning of the sequence? How could the contribution from this be removed? 6 Chapter 8: Relaxation E8-1. In an inversion-recovery experiment the following peak heights (S, arbitrary units) were measured as a function of the delay, t, in the sequence: t / s 0.1 0.5 0.9 1.3 1.7 2.1 2.5 2.9 S ­98.8 ­3.4 52.2 82.5 102.7 115.2 120.7 125.1 The peak height after a single 90° pulse was measured as 130.0 Use a graphical method to analyse these data and hence determine a value for the longitudinal relaxation rate constant and the corresponding value of the relaxation time, T1. E8-2. In an experiment to estimate T1 using the sequence [180° ­ ­ 90°] acquire three peaks in the spectrum were observed to go through a null at 0.5, 0.6 and 0.8 s respectively. Estimate T1 for each of these resonances. A solvent resonance was still inverted after a delay of 1.5 s; what does this tell you about the relaxation time of the solvent? *E8-3. Using the diagram at the top of page 8­5, write down expressions for dn1/dt, dn2/dt etc. in terms of the rate constants W and the populations ni. [Do this without looking at the expressions given on page 8­6 and then check carefully to see that you have the correct expressions]. *E8-4. Imagine a modified experiment, designed to record a transient NOE enhancement, in which rather than spin S being inverted at the beginning of the experiment, it is saturated. The initial conditions are thus I I Sz z z0 0 00 ( ) = ( ) = Using these starting conditions rather than those of Eq. [16] on page 8-10, show that in the initial rate limit the NOE enhancement builds up at a rate proportional to IS rather than 2IS. You should use the method given in Section 8.4.1 for your analysis. Without detailed calculation, sketch a graph, analogous to that given on page 8- 12, for the behaviour of Iz and Sz for these new initial conditions as a function of mixing time. E8-5. Why is it that in a two spin system the size of transient NOE enhancements depends on RI , RS and IS, whereas in a steady state experiment the enhancement only depends on RI and IS? [Spin S is the target]. In a particular two-spin system, S relaxes quickly and I relaxes slowly. Which experiment would you choose in order to measure the NOE enhancement between these two spins? Include in your answer an explanation of which spin you would irradiate. 7 E8-6. For the molecule shown on the right, a transient NOE experiment in which HB is inverted gave equal initial NOE build-up rates on HA and HC. If HA was inverted the initial build-up rate on HB was the same as in the first experiment; no enhancement is seen of HC. In steady state experiments, irradiation of HB gave equal enhancements on HA and HB. However, irradiation of HA gave a much smaller enhancement on HB than for the case where HB was the irradiated spin and the enhancement was observed on HA. Explain. Z HA HB HC X Y E8-7. What do you understand by the terms correlation time and spectral density? Why are these quantities important in determining NMR relaxation rate constants? E8-8. The simplest form of the spectral density, J(), is the Lorentzian: J ( ) = + 2 1 2 c c 2 Describe how this spectral density varies with both and c. For a given frequency, 0, at what correlation time is the spectral density a maximum? Show how this form of the spectral density leads to the expectation that, for a given Larmor frequency, T1 will have a minimum value at a certain value of the correlation time, c. E8-9. Suppose that he Larmor frequency (for proton) is 800 MHz. What correlation time will give the minimum value for T1? What kind of molecule might have such a correlation time? E8-10. Explain why the NOE enhancements observed in small molecules are positive whereas those observed for large molecules are negative. E8-11. Explain how it is possible for the sign of an NOE enhancement to change when the magnetic field strength used by the spectrometer is changed. E8-12. What is transverse relaxation and how it is different from longitudinal relaxation? Explain why it is that the rate constant for transverse relaxation increases with increasing correlation times, whereas that for longitudinal relaxation goes through a maximum. 8 Chapter 9: Coherence selection: phase cycling and gradient pulses E9-1. (a) Show, using vector diagrams like those of section 9.1.6, that in a pulse-acquire experiment a phase cycle in which the pulse goes x, y, ­x, ­y and in which the receiver phase is fixed leads to no signal after four transients have been co-added. (b) In a simple spin echo sequence 90° ­ ­ 180° ­ ­ the EXORCYCLE sequence involves cycling the 180° pulse x, y, ­x, ­y and the receiver x, ­x, x, ­x. Suppose that, by accident, the 180° pulse has been omitted. Use vector pictures to show that the four step phase cycle cancels all the signal. (c) In the simple echo sequence, suppose that there is some z-magnetization present at the end of the first delay; also suppose that the 180° pulse is imperfect so that some of the z-magnetization is made transverse. Show that the four steps of EXORCYCLE cancels the signal arising from this magnetization. *E9-2. (a) For the INEPT pulse sequence of section 9.1.8, confirm with product operator calculations that: [You should ignore the evolution of offsets as this is refocused by the spin echo; assume that the spin echo delay is 1/(2JIS)]. (i) the sign of the signal transferred from I to S is altered by changing the phase of the second I spin 90° pulse from y to ­y; (ii) the signs of both the transferred signal and the signal originating from equilibrium S spin magnetization, Sz, are altered by changing the phase of the first S spin 90° pulse by 180°. On the basis of your answers to (i) and (ii), suggest a suitable phase cycle, different to that given in the notes, for eliminating the contribution from the equilibrium S spin magnetization. (b) Imagine that in the INEPT sequence the first I spin 180° pulse is cycled x, y, ­x, ­y. Without detailed calculations, deduce the effect of this cycle on the transferred signal and hence determine a suitable phase cycle for the receiver [hint - this 180° pulse is just forming a spin echo]. Does your cycle eliminate the contribution from the equilibrium S spin magnetization? (c) Suppose now that the first S spin 180° pulse is cycled x, y, ­x, ­y; what effect does this have on the signal transferred from I to S? E9-3. Determine the coherence order or orders of each of the following operators [you will need to express Ix and Iy in terms of the raising and lowering operators, see section 9.3.1] I I I I I I I I I I I I Iz x y x z x x y y1 2 1 2 3 1 1 1 2 1 2 1 24 2 2 2+ - + + +( ) In a heteronuclear system a coherence order can be assigned to each spin 9 separately. If I and S represent different nuclei, assign separate coherence orders for the I and S spins to the following operators I S I S I Sx y x z x x2 2 E9-4. (a) Consider the phase cycle devised in section 9.5.1 which was designed to select p = ­3: the pulse phase goes 0, 90, 180, 270 and the receiver phase goes 0, 270, 180, 90. Complete the following table and use it to show that such a cycle cancels signals arising from a pathway with p = 0. step pulse phase phase shift experienced by pathway with p = 0 equivalent phase rx. phase for p = ­3 difference 1 0 0 2 90 270 3 180 180 4 270 90 Construct a similar table to show that a pathway with p = ­1 is cancelled, but that one with p = +5 is selected by this cycle. (b) Bodenhausen et al. have introduced a notation in which the sequence of possible p values is written out in a line; the values of p which are selected by the cycle are put into bold print, and those that are rejected are put into parenthesis, viz (1). Use this notation to describe the pathways selected and rejected by the cycle given above for pathways with p between ­5 and +5 [the fate of several pathways is given in section 9.5.1, you have worked out two more in part (a) and you may also assume that the pathways with p = ­5, ­4, ­2, 3 and 4 are rejected]. Confirm that, as expected for this four-step cycle, the selected values of p are separated by 4. (c) Complete the following table for a three-step cycle designed to select p = +1. step pulse phase phase shift experienced by pathway with p = +1 equivalent phase rx. phase 1 0 2 120° 4 240° (d) Without drawing up further tables, use the general rules of section 9.5.2 to show that, in Bodenhausen's notation, the selectivity of the cycle devised in (c) can be written: ­2 (­1) (0) 1 (2) (e) Use Bodenhausen's notation to describe the selectivity of a 6 step cycle designed to select p = +1; consider p values in the range ­6 to +6. E9-5. Draw coherence transfer pathways for (a) four-quantum filtered COSY 10 [use the sequence in section 9.5.5.4 as a model]; (b) a 180° pulse used to refocus double-quantum coherence; (c) N-type NOESY. E9-6. Write down four-step phase cycles to select (a) p = ­1 and (b) p = +2. Suppose that the cycles are applied to different pulses. Combine them to give a 16-step cycle as was done in section 9.5.4; give the required receiver phase shifts. *E9-7. The CTP and pulse sequence of triple-quantum filtered COSY are t1 t2 0 ­1 ­2 ­3 1 2 3 (a) Write down the values of p brought about by (i) the first pulse, (iii) the second pulse, (iii) the first and second pulses acting together and considered as a group, (iv) the last pulse. (b) Imagine the spin system under consideration is able to support multiple quantum coherence up to and including p = 4. Consider a phase cycle in which the first two pulses are cycled as a group and, having in mind your answer to (a) (iii), use the notation of Bodenhausen to indicate which pathways need to be selected and which blocked. Hence argue that the required phase cycle must have 6 steps. Draw up such a six-step phase cycle and confirm that the proposed sequence of pulse and receiver phases does indeed discriminate against filtration through double-quantum coherence. (c) Consider an alternative phase cycle in which just the phase of the last pulse is cycled. As in (b), use Bodenhausen's notation to describe the wanted and unwanted values of p. Devise a suitable phase cycle to select the required values of p. (d) Try to devise a cycle which involves shifting just the phase of the second pulse. E9-8. (a) Write down a 16 step cycle which selects the pathways shown in the double quantum spectroscopy pulse sequence of section 9.5.9.1; include in your cycle double-quantum selection and EXORCYCLE phase cycling of the 180° pulse. (b) Write down an 8 step cycle which selects the pathway for NOESY shown in section 9.5.9.2; include in your cycle explicit axial peak suppression steps. *E9-9. The following sequence is one designed to measure the relaxation- induced decay of double-quantum coherence as a function of the time 2 11 0 ­1 ­2 1 2 The 180° pulse placed in the middle of the double-quantum period is used to refocus evolution due to offsets and inhomogeneous line broadening. Devise a suitable phase cycle for the second 180° pulse bearing in mind that the 180° pulse may be imperfect. [hint: are four steps sufficient?] E9-10. Use the formula given in section 9.6.2 for the overall decay of magnetization during a gradient 2 Gtrmax to calculate how long a gradient is needed to dephase magnetization to (a) 10% and (b) 1% of its initial value assuming that: G = 0.1 T m­1 (10 G cm­1 ), rmax = 0.005 m (0.5 cm) and = 2.8 × 108 rad s­1 . [Put all the quantities in SI units]. E9-11. Imagine that two gradients, G1 and G2, are placed before and after a radiofrequency pulse. For each of the following ratios between the two gradients, identify two coherence transfer pathways which will be refocused: (a) G1:G2 = 1:1 (b) G1:G2 = ­1:1 (c) G1:G2 = 1:­2 (d) G1:G2 = 0.5:1 E9-12. Determine the ratio G1:G2 needed to select the following pathways: (a) p = 2 1 (b) p = 3 1 (c) p = ­3 1 (d) p = ­1 1 and p = 1 ­1 (e) p = 0 1 Comment on the way in which case (e) differs from all the others. E9-13. Consider a gradient selected N-type DQF COSY t1 G1 G2 G3 t2 0 ­1 ­2 1 2 We use three gradients; G1 in t1 so as to select p = +1 during t1; G2 to select double quantum during the filter delay and G3 to refocus prior to acquisition. (a) Show that the pathway shown, which can de denoted 012­1, is 12 selected by gradients in the ratio G1:G2:G3 = 1:1:3. (b) Show that this set of gradients also selects the pathway 0­14­1. What kind of spectrum does such a pathway give rise to? (c) Consider gradients in the ratios G1:G2:G3 (i) 1: 1 2 :2 and (ii) 1: 1 3 : 5 3 . Show that these combination select the DQ filtered pathway desired. In each case, give another possible pathway which has p = 1 during t1 and p = ­1 during t2 that these gradient combinations select. (d) In the light of (b) and (c), consider the utility of the gradient ratio 1.0 : 0.8 : 2.6 *E9-14. Devise a gradient selected version of the triple-quantum filtered COSY experiment, whose basic pulse sequence and CTP was given in E9-7. Your sequence should include recommendations for the relative size of the gradients used. The resulting spectrum must have pure phase (i.e. p = 1 must be preserved in t1) and phase errors due to the evolution of offsets during the gradients must be removed. How would you expect the sensitivity of your sequence to compare with its phase-cycled counterpart? *E9-1. A possible sequence for P/N selected HMQC is t2 1 0 ­1 t1 1 0 ­1 a b 13 C 1H pI pS g G1 G2 The intention is to recombine P- and N-type spectra so as to obtain absorption mode spectra. (a) Draw CTPs for the P-type and N-type versions of this experiment [refer to section 9.6.7.3 for some hints]. (b) What is the purpose of the two 180° pulses a and b, and why are such pulses needed for both proton and carbon-13? (c) Given that H/C = 4, what ratios of gradients are needed for the P-type and the N-type spectra? (d) Compare this sequence with that given in section 9.6.7.3, pointing out any advantages and disadvantages that each has.