1. Nuclear Magnetic Resonance Spectroscopy Workshop
Objectives: By the end of this workshop you will be able to ...
describe how n.m.r. spectra are obtained and how they can
be used to tell us about the structure of an organic molecule.
use low-resolution proton n.m.r. spectra to identify different
chemical environments within a molecule (including use
of the integration trace and chemical shift values).
explain how the fine structure in high-res spectra arises and
use it to find the identity of unknown samples (using mass
and i.r. spectra as additional evidence where necessary).
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2. Main Menu Introduction to Nuclear Magnetic Resonance
Interpreting NMR spectra
Using spectra to identify molecules
Assessment For Learning Task
View NMR section in Edexcel A2 Specification
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NMR Chemical Shift data
IR data
NMR IR
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3. Introduction to Nuclear Magnetic Resonance
What is resonance?
A model of magnetic resonance
How an NMR spectrometer works
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Magnetic moments!
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4. Examples of
resonance
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(so what is it?)
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5. So what is nuclear magnetic resonance?
Some nuclei can act like little magnets. They will line up with an external field but can be flipped to oppose the field if the correct amount of energy is applied. They will then
relax back to their ground state
when the energy input ceases.
This flipping occurs because atomic nuclei are so small that the alignment is quantised.
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The energy required to resonate the nuclei depends on the element and on the size of the external field, but is usually around 60 – 100 MHz for hydrogen when we carry out NMR. (Radio 1 is 98.8MHz so that would do!) We can investigate what affects this resonant frequency using this equipment ...
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6. A model of magnetic resonance
Magnetic stirrer
(oscillator)
Permanent magnet
Compass needle
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Switch on the magnetic stirrer and very slowly increase the frequency
of oscillations (i.e. turn its speed up) until you hit the resonant frequency of the compass ... you will see it swing wildly!
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Try achieving the resonance again by fixing the speed (frequency) and moving the permanent magnet closer to increase the field strength.
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7. Investigating magnetic resonance
If you are very careful, you can slowly increase the frequency and get each compass needle to resonate individually.
What effect does shielding the compass needle (e.g. with iron) have on the resonance?
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Are the other resonances affected?
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8. How an NMR spectrometer works
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A typical machine for proton NMR will need to operate at 60–100 MHz requiring a field strength of 1.4 – 2.3 Tesla. The high fields at the top end of this range require superconducting magnets which must be cooled by liquid helium. Many modern research NMR machines can run at MHz and there are even 800MHz machines in use with fields of more than 23 Tesla. A 1GHz machine is undergoing tests!
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9. NMR spectrometer gallery 1
A 60MHz NMR machine...
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... and its superconducting 600MHz cousin
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10. NMR spectrometer gallery 2
An NMR machine for probing proteins
and an 800MHz behemoth!
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A medical NMR scanner (MRI machine)
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11. Magnetic moments! 1H
Only nuclei with a magnetic moment will be able to undergo nuclear magnetic resonance
This means nuclei with an odd number of
protons, or an odd number of neutrons ... or both!
But what effect does the environment within a molecule have on the resonance?
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12. Interpreting Nuclear Magnetic Resonance Spectra
PN1 and PN2 (Low-Resolution)
PN2 (Low-Res) and PN3 (High-Res)
PN4
PN5
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PN6
PN7
PN8
PN9
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NMR Chemical Shift data
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14. NMR
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15. NMR
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16. NMR
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17. NMR
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18. NMR
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19. NMR
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20. NMR
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21. Using spectra to identify organic molecules
For each task you will be given the mass, proton nmr and infrared spectrum of an unknown organic molecule. Discuss the data with your partner and attempt to determine the molecule. Be prepared to give evidence for your structure.
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Task 1
Task 2
Task 3
Task 4
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NMR Chemical Shift data
IR data
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22. Help with tasks
The mass spectrum will give you the relative molecular mass. I have marked the parent (molecule) ion on each spectrum with *. You should identify possible fragments (all 1+ ions) for the major peaks.
The proton n.m.r. spectrum will indicate the number of different kinds (environments) of hydrogens in your molecule. I have provided the ratio of areas under the peaks and an indication of the splitting pattern in case it is not clearly visible.
i.e. 1H 2H etc gives ratio of areas under peaks
NMR
s = singlet d = doublet t = triplet q = quartet
sept = septet m = complex (unresolved) multiplet IR
t/d = triplet of doublets etc
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The i.r. spectrum can be used to deduce of confirm the presence of particular bonds (such as carbonyls and hydroxyls) in your molecule. Remember the effect of H-bonding on the infrared spectrum.
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23. Task 1
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NMR Spectrum
IR Spectrum
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24. Task 1
NMR
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Mass Spectrum
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25. Task 1 IR
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26. Task 2
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27. Task 2
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28. Task 2 IR
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29. Task 3
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30. Task 3
NMR
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31. Task 3 IR
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32. Task 4
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33. Task 4
NMR
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34. Task 4 IR
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35. Edexcel A2 Specification
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