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Part I Chemical Engineering Section 2 (ex-ET)
ANALYTICAL CHEMISTRY
8 lectures, Lent Term 2012
Prof. Clemens Kaminski
Course outline
1. What is Analytical Chemistry?2. General features of molecular spectroscopy
3. Ultraviolet/visible spectroscopy
4. Infrared spectroscopy
5. Microwave spectroscopy
6. Nuclear magnetic resonance spectroscopy
7. Methods of elemental analysis
8. Mass spectrometry
9.
Chromatography
Text books
These lecture notes contain all you need to know about analytical chemistry for examination
purposes. You can find out more (if you want to) from almost any textbook with “Physical
Chemistry” or “Analytical Chemistry” in the title.
Examples paper: One examples paper will be issued to test understanding and aid exam
preparation.
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1 What is Analytical Chemistry?
Analytical Chemistry is concerned with answering the questions:
• What chemical species are present in a sample?
• How much of each chemical species is present?
Analytical Chemistry is vital in the following areas:
• Quality control in the process industries
o of starting materials
o of intermediates
o of products
confirmation of purity
identification of impurities
• Environmental analysis
o Monitoring and control of pollutants in streams that are to be released
to the environment (in gas, liquid or solid form)
o Measurement of pollutants in the environment (air/river/ground)
NOx, SOx, hydrocarbons in atmosphere
Organic chemicals (polychlorinated biphenyls, detergents)
Toxic heavy metals (lead, cadmium, mercury)
• Clinical and biological studies
o Measurement of nutrients, including trace metals
o Measurement of naturally produced chemicals (cholesterol, sugar, urea)
o Measurement of drug levels in body
• Geological assays
o Measurement of metal concentrations in ores and minerals
o Measurement of oil/gas concentrations in rocks
• Fundamental and applied research
o Chemical engineering: how much conversion (or separation) do we obtain under
these conditions?
o Organic molecule synthesis: what compound have we made?
Analytical Chemistry is thus vital in the process industries and in research laboratories.
• Qualitative analysis is the identification of elements, functional groups, or
particular compounds in a sample.
• Quantitative analysis is the determination of the amount of a particular
element, species or compound in a sample.
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Analytical Chemists need to be good at careful accurate measurements, statistics and error
analysis:
• samples of known concentration must often be prepared for calibration purposes
• samples must not become contaminated
• for environmental analysis, more than one measurement is often performed on more than
one sample to draw conclusions.
On a process plant, analytical chemistry is normally performed “off-line”:
• a sample of product is removed and sent to the lab for testing – might take hours or days
• for plant control purposes, we may need to infer composition indirectly
o e.g. from T and P measurements and a model of how conversion (or separation)
varies with T and P
• numerous off-line analytical techniques.
However, an increasing number of analytical techniques can now be performed “on-line”:
• sample the process stream “in situ”
• the plant can then be controlled using the direct composition measurement
• fewer techniques, and most will only work for certain reactions/products.
Classical (old-fashioned) analytical chemistry is based on techniques such as:
• Titration: volume of a standard reagent reacting with the sample is measuredo Acid-base titrations: e.g. monitor the colour of a solution containing a
pH-sensitive indicator as an acid (or base) is added.
o Complexation titrations: e.g. monitor the pH of a solution whilst reagent EDTA,
ethylenediaminetetraacetic acid (HOOCCH2)2 NCH2CH2 N(CH2COOH)2, is added:
EDTA reacts in a 1:1 molar ratio with almost all metal cations (except
alkali metals), enabling the metal cation concentration to be determined.
• Gravimetry: measurements based on mass. Simple examples are:
o Mass lost on heating of a solid gives the amount of water of crystallisation.
o Mass of precipitate formed during a reaction can be measured.
For instance, adding excess silver nitrate solution to determine the
concentration of chloride ions present.
• Electrochemical methods:
o pH measurement.
o Ion-selective electrodes.
Modern analytical chemistry is largely based on instrumental techniques. In this lecture
course, we shall discuss:
• Molecular spectroscopy techniques: first part of course
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• Other analytical techniques: last two lectures
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2 General features of molecular spectroscopy
• Quantum mechanics tells us that all energy levels are quantised.
• We can probe the separation between energy levels by spectroscopy:
o Test of quantum mechanics and our theories of bonding
o Provides structural information
2.1 Absorption and Emission
• The “ground state” of a molecule is the one of lowest energy.
• An “excited state” of a molecule is one of higher energy.
• “Excitation” refers to the process in which the molecule goes from a low to high energy
state: it requires the addition of energy by photon absorption.
• “Relaxation” is the process by which a molecule falls from a high to low energy state: it
involves the removal of energy by photon emission.
• Whether the transition is permitted or not depends on:
o The frequency of the photon: we require Δ E = h ν
o Selection rules: we require that the electromagnetic radiation interact
with the molecule, and that angular momentum is conserved as well as energy.
[Aside: photons have an intrinsic angular momentum…] For example: an electron jumping between atomic orbitals has to obey:
Δn = anything ; Δl = ±1 ; Δml = 0, ±1
This means an electron in the 1s orbital of a hydrogen atom could move to
2p, 3p, or 4p orbitals by absorption of light of appropriate frequency, but
not to 2s, 3s, 4s, or 3d, 4d atomic orbitals.
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2.2 Schematic diagram of an absorption spectrometer
• The monochromator causes light of just a single frequency of light to be
detected; it may be before or after the sample cell.
• The monochromator is adjusted (e.g. by rotation of the prism) so that the frequency of
light reaching the detected is scanned.
• This simple diagram is sufficient for this course. However, in practice better methods
have been developed than this basic set-up:
o Tunable diode lasers may be used: in this case, the light source is monochromatic
but its frequency can be “tuned”.
o Fourier transform infrared (FTIR) spectrometers use an interferometer technique.
o NMR spectrometers use a very short pulse of radiation containing a distribution of
frequencies.
2.3 Factors affecting intensities of spectral lines
• Transition Probability
o This depends on the precise quantum mechanical wavefunctions of the initial and
final states (beyond the level of this course).
Some transitions may have zero probability – in that case, they are said to
violate “selection rules”.• The Population of States
o The initial population of an energy level obviously affects spectral intensities.
o At thermal equilibrium, the relative populations of two energy levels may be
obtained from the Boltzmann factor:
k is Boltzmann’s constant, 1.38066 x 10 –23 J/K
upper
Carrie
Δ E
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When Δ E >> kT , then only the lower level has significant population
When Δ E << kT , then the energy levels will have the almost identical
populations
• Path length and concentration of sample
o This is summarised by the Beer-Lambert law:
log10 ( I / I 0) = – ε [conc] L
“Transmittance” = I / I 0
“Absorbance” = –log10 ( I / I 0) [formerly known as “optical density”,
O.D.]
o Hence an alternative expression of the Beer-Lambert law is:
Absorbance = ε [conc] L
o The constant of proportionality ε is termed the molar absorption coefficient
[former term is “extinction coefficient”].
ε has units; if they’re not quoted, assume that they are in mol –1 dm3 cm –1
2.4 Spectroscopic units
• A variety of different units are commonly used in spectroscopy to represent the energy
difference between the levels. You need to be familiar with:
o J (Joules), the SI unit of energy
o ν (frequency, often expressed in MHz); related by Δ E = h ν
o (wavelength, often expressed in nm), related by Δ E = hc / .o 1/ or (reciprocal wavelength, or wavenumbers, often expressed in
cm –1); related by Δ E = h c (1/ ).
o eV (electron volts), related by 1 eV = 1.602 x 10 –19 J (i.e. the charge of an
electron)
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2.5 Regions of the electromagnetic spectrum
Depending on the wavelength used a variety of different structural information
may be obtained.
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3 Ultraviolet/visible (UV/vis) spectroscopy
• Absorption in the UV/visible region is associated with transitions between electronic
energy levels.
o Colours of compounds/solutions arise in this way.
• The transition of interest is normally that between the highest occupiedmolecular orbital (HOMO) and the lowest unoccupied molecular orbital
(LUMO).
o Other transitions involve greater energy separations, and so are further away from
the visible region; band overlap for transitions at higher energies tends to result in
uninformative spectra.
o Wavelengths below ~200 nm cannot easily be studied for instrumental reasons -
the sample cell window absorbs radiation at these wavelengths.
• The UV spectrum is normally plotted as the absorbance against wavelength; peak
positions are identified by quoting λmax and ε.
• Typical UV spectrum:
molecular orbitals
HOMO
LUMO
Δ E for transition of interest
Energy
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(from http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/UV-Vis/spectrum.htm#uv3)
• Aside: due to simultaneous vibrational and rotational transitions (see Sections 3 and 4),
UV spectra normally consist of fairly broad peaks.
• The absorbing groups in a molecule are called chromophores. Two isolated
chromophores in a molecule give roughly independent absorptions for each one:
o e.g. CH3CH2 – CNS: max= 245 nm and ε = 800
SNC –CH2CH2CH2 – CNS: max= 247 nm and ε = 2000
• In organic chemistry, π -conjugated systems (when multiple bonds are separated
by a single bond) tend to give particularly informative spectra.
o Overlap of adjacent π orbitals results in a decrease in the energy gap between the
occupied π orbital and the unoccupied π * antibonding orbital.
o This results in an increase in absorption wavelength (even into the visible region
for greatly conjugated systems e.g. organic dyes), and normally an
increase in the intensity as well.
General rule: increased conjugation increases λmax and ε.
o Aromatic systems exhibit conjugation, but tend to give complex spectra,
frequently with more than one absorption band.
• Conjugation with lone pairs (n-π conjugation) can also result in spectral transitions,
though these are much weaker than those originating from overlap of π orbitals.
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Example UV spectrum results:
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3.1 Uses of UV/vis spectroscopy
• Sample is usually liquid.
• Can follow changes in colour/composition quite rapidly (timescale may be down to ~1 s).
• Can measure concentration of any coloured compound, or any compound that absorbs in
the UV region.
• Beer-Lambert law is useful, though for accurate work absorbance will be
measured on solutions of known concentration for calibration purposes.
• Reasonably straightforward to do the measurement “on-line”:
o Can study the process fluid through a glass window, or using a fibre optic cable.
o In practice, a technique called attenuated total reflectance is likely to be used if the
sample absorbs strongly.
• This technique is limited:
o It doesn’t work if the sample doesn’t absorb in the UV/vis region!
o It’s not good if the sample contains several species that absorb in the UV/vis
region: the absorption bands are broad and so overlap too much.
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4 Infrared spectroscopy
• Absorption in the infrared region is associated with transitions between vibrational energy
levels.
4.1 Diatomic molecules: ideal case
• Let us consider a diatomic molecule first (such as H–Cl) as it contains just a single bond.
• Imagine the bond behaves like a perfect spring with a force constant k
• This is often called the “simple harmonic oscillator” (SHO)
approximation.
• We can solve the Schrödinger equation exactly in this case to derive the energy levels of
the molecule
• The vibrational energy levels are characterised by a quantum number v.
o E = h ν0 (v + ½) v = 0, 1, 2, …
o [Note that this corresponds to the vibration frequency of the
spring]
µ is the “reduced mass”, given by
• At room temperature,ΔE >> kT , implying that only the v = 0 quantum level is
significantly populated.
m1 m2
spring constant = k
vibrational energy levelsEnergy
v = 0
v = 1
v = 2
v = 3
v = 4
Δ E
E = 1/2 h ν0
E = 3/2 h ν0
E = 5/2 h ν0
E = 7/2 h ν0
E = 9/2 h ν0
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• The first selection rule is thatΔv = ±1
o This means that for a diatomic molecule we expect to see a single absorption peak
corresponding to Δ E = h ν0
o The peak tells us ν0, the bond vibration frequency, from which we get information
about k and/or µ.
• The second selection rule is that the bond has to have a permanent dipolemoment:
o Variation of the molecule’s dipole moment upon vibration is needed to interact
with the oscillating electric vector of the electromagnetic radiation.
o This means that diatomic molecules such as O2 and N2 won’t show any absorption
in the infrared region (and so aren’t greenhouse gases…); a molecule such as HCl
will show absorption in the infrared region.
4.2 Diatomic molecules: real case
• Real bonds do not behave as ideal springs; they behave as anharmonic oscillators.
• Potential energy diagram:
• The simple harmonic oscillator SHO model discussed earlier provides a good
approximation to the real case at the lowest energy level when r is always close to
r equilibrium.
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• For real molecules, the bond will break at high energies before v → ∞.
o In practice this means that the vibrational energy levels get closer together as
quantum number v goes up.
• Selection rules for real diatomic molecules:
o Δv = ±1 (as for SHO), but Δv = ±2, ±3,… are now weakly allowed as well
(transition probability is small but is now greater than zero).
o Molecule still needs to have a dipole moment for interaction with photon to occur.
• It’s still the case that only the v = 0 level is significantly populated at room temperature.
• Spectrum will thus show an absorption band at ν0, plus a weak band at ~2ν0 and possibly
~3ν0
• Note that the ground state of the molecule (i.e. the state of lowest energy) doesn’t have
E = 0. Two consequences of this are:
o Even at a temperature of absolute zero, bonds will still have a non-zero vibrational
energy that depends on k and µ:
The molecule is said to possess zero-point energy.
Atoms still move by vibrations at absolute zero; whilst seen here from themaths, it’s a consequence of the Heisenberg uncertainty principle.
o Consider bonds involving different isotopes, e.g. compare
O–H and O–D bonds:
They involve the same number of electrons, and so have identical force
constants and bond lengths.
However, they have different zero-point energies because of different µ.
They will have different bond dissociation energies, as this is
the energy required to take the bond from its zero-point energy up to an
energy corresponding to the atoms being widely separated.
vibrational energy levelsEnergy
v = 0
v = 1
v = 2
v = 3
v = 4
Δ E
E =1
/2 h ν0
E = ~ 3/2 h ν0
E = ~ 5/2 h ν0
E = ~ 7/2 h ν0
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4.3 Polyatomic molecules
• Polyatomic molecules have more than one vibrational mode.
o The location of all N atoms in a molecule needs 3 N parameters to specify it. These
are normally specified by:
Translational position: specify the centre of gravity of the molecule using
3 parameters.
Rotational motion: requires 2 parameters for a linear molecule; 3
parameters for a non-linear molecule.
Vibrational modes: there will thus be 3 N –5 of these for a linear molecule,
and 3 N –6 of these for a non-linear molecule.
• The vibrational modes in polyatomic molecules may involve movement of all the atoms,
rather than just a single bond vibration.
• Each vibrational mode will have its own frequency. For example, the three vibrational
modes of the water molecule are:
Symmetic stretch Asymmetric stretch Bending mode
ν1 = 3655 cm –1
ν2 = 1595 cm –1
ν3 = 3755 cm –1
• Each vibrational mode can be considered individually.
• We therefore expect absorptions at frequencies corresponding to ν1, ν2, ν3,… providing the
dipole moment of the molecule is changing during the vibration (as was the case for
diatomic molecules).o All three vibrational modes of H2O are IR-active
o The symmetric stretch of CO2 is IR-inactive as it doesn’t change the
dipole moment); the other vibrational modes of CO2 are IR-active
o Note that H2O and CO2 are greenhouse gases because they absorb in the infrared
region.
• Overtone and combination bands (e.g. 2ν1, ν1+ν3) are very weakly
allowed (as was the case for real diatomic molecules).
O
H
H
O
H
H
O
H
H
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4.4 Uses of IR spectroscopy
• The frequencies of some vibrational modes are almost independent of thestructure of the compound in which they are located.
o For instance, O–H stretching vibrations occur at 3200-3600 cm –1
Detecting an absorption band in this frequency range is evidence that the
sample contains O–H functional groups
[Aside: it’s quite a broad range in this case because O–H bond strengths
are affected by the extent of hydrogen bonding to them]
• We can thus use IR spectroscopy to identify structural groups present in the sample:
• From our discussion above, we note that:
o Bonds involving lighter atoms absorb at higher frequency
than bonds involving heavier atoms: C–H > C–C O–H > O–D
o Stronger bonds absorb at higher frequencies:
C≡C 2150 cm –1 C=C 1650 cm –1
o Bonds with large dipole moments give strong absorptions; those without give
weak (or no) absorption:
C=O strong C=C often weak
• Organic chemists used to be very good at knowing precise vibrational frequencies of
different functional groups and how there were affected by substituents.
o For instance, they’d know 1710 cm –1 was likely to be a C=O group in a ketone,
while recognising 1730 cm –1 was more likely to be a C=O group of an aldehdye.
• However, structural identification is now almost always done by comparison of the
spectrum obtained with one in a database: a fingerprint method of identification.
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Example IR spectrum:
(from http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/InfraRed/infrared.htm#ir1)
• • The sample for IR spectroscopy may be solid/liquid/gas.
• For lab measurements, the sample is held in a special cell:
o the windows shouldn’t absorb above ~500 cm –1 (e.g. can’t use glass; KBr is quite
common)
o the path length is usually short (because absorbances tend to be strong).
• Beer-Lambert law can be used to estimate concentration; this is difficult in practice to do
accurately due to scattered radiation affecting the baseline.
• Limitation: need to identify a band from the component of interest that isn’t overlapping
with bands from any other components that may be present; usually okay for simple
mixtures.
• Rough cost estimate of basic spectrometer: £12k
• Timescale: Typically 10 s for a modern instrument, but it depends on sensitivity and
resolution required.
• On-line measurement of process fluids is not straightforward:
o Most of the materials used for cell windows aren’t resistant to chemicals (e.g. KBr
dissolves in water).
o Normal fibre optic cables absorb in the infrared region so we can’t use them.
o Special materials for fibre optic cables that don’t absorb above, say, 800 cm –1 are
being developed; thus far they tend to be expensive and react with acid/alkali.
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• Alternative on-line measurement technique: investigate the near-infrared (NIR) region
instead (wavenumbers between 4500 and 12,000 cm –1):
o Fibre optic cables do exist that don’t absorb in this region, so remote sensing is
possible.
o We’ll only see weak overtone and combination bands (e.g. 2ν1 and ν1 + ν2) rather
than fundamental vibrations; spectra are far harder to interpret.
There tend to be lots of weak overlapping bands in this region,
Calibrations involve running pure components and developing a
mathematical model of the behaviour for mixtures – very time consuming
process
o The NIR method is now used for continuous monitoring of some
bulk chemicals in industry (e.g. gasoline; polymer melts), and is just beginning to
be used in food and pharmaceutical industry.
Example: NIR spectra of C-H stretching overtone region for water-ethanol mixtures.
(www.axsun.com)
• New techniques are being devised for on-line process analysis – one called Encoded
Photometric Infrared (EPIR) spectroscopy has great potential, but it’s too early to say
how useful it will be.
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4.5 Raman vibrational spectroscopy
• Raman spectroscopy is another way of doing vibrational spectroscopy.
• Let us consider what happens when a laser emitting fixed frequency light is fired at a
sample.
• Most photons scattered by a sample will be at the same frequency as the incident light:
o Photons interact with the sample.
o During interaction, the molecule is raised from the v = 0 vibrational level to a so-
called “virtual state”.
o Usually the molecule then relaxes back down to the v = 0 level.
o The scattered photon thus has the same frequency as before – this is termed
“elastic scattering” or “Rayleigh scattering”.
• However, a very small number of photons (~1 in 107) will be scattered at a different
(usually lower) frequency than the incident light:
o This effect is called the “Raman effect”.
o During the photon interaction with the sample, the molecule in the virtual state
may relax back to the v =1 vibrational state.
o In this case, photons will have a scattered frequency of
vlaser – ν0 where ν0 is the vibration frequency.
o Hence we can measure the vibrational frequency ν0.
o Other transitions may also occur (e.g. from initial v = 1 level to level v = 0 or v = 2).
• The selection rule for Raman spectroscopy is different to that for infrared
vibrational spectroscopy:
o Raman bands require there to be a change in polarizability of the molecule upon
vibration; there’s no need for there to be a changing dipole moment.
o As a result, bands that are inactive in IR spectroscopy are normally active in
Raman spectroscopy.
o Similarly bands that are weak in IR spectroscopy (because they don’t changedipole moment much) are usually strong in Raman spectroscopy.
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• Example: IR and Raman spectrum of L-cystine illustrating the different selection rules
(www.jascofrance.fr):
• Another advantage: light at the laser frequency can be focussed on to a small area of
sample easily – Raman microscopy can record a vibrational spectrum on just a
small part of the sample (down to ~1 µm).• Main limitations:
o if the laser also promotes electrons into a higher energy level, then light will be
emitted as the electron relaxes back down – hence there may be interference from sample fluorescence
o interference from background radiation
o quantifying signal – the Beer-Lambert law doesn’t apply
o it’s not good for complex mixtures
• Rough cost estimate of basic spectrometer: £15k ?
• Raman spectroscopy is beginning to be used for on-line process analysis:
o the laser can be in the near-infrared region meaning that it can travel through glass
windows, or be transported by fibre optic cables; the latter makes possible remote
on-line sensing of the process fluid.
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• Example: in-situ Raman spectra of the polymerisation of styrene (C6H5CH=CH2) in a
batch reactor as a function of time (in minutes).
(http://www.surrey.ac.uk/PRC/Facilities/raman.htm)
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5 Microwave Spectroscopy
• This technique is not really useful in analytical chemistry, but is covered briefly here for
completeness and because it can impact vibrational spectra.
• Absorption in the microwave region is associated with transitions between rotational
energy levels.
o This is how microwave ovens work.
5.1 Pure rotational spectroscopy
• We shall only consider linear molecules in this section (e.g. diatomic molecules, or CO 2).
• In the same way that we write down and solve the Schrödinger equation for vibrations we
can also do so for pure rotational motion.
• For rigid linear molecules this gives energy levels characterised by the quantum numbers
J and M J
o E = B J (J+1) J = 0, 1, 2, 3, …
o M J = J , J –1, J –2, …, – J [i.e. there are 2 J +1 values of M J ]
o where I is the moment of inertia
Note that I = µ r 2 for a diatomic molecule, where µ is the reduced mass
• Selection rules:
o Δ J = ±1 [to conserve angular momentum]
o Molecule needs a permanent dipole moment (to interact with EMR)
• Population of levels depends on the degeneracy (number of levels having the same
energy) and the Boltzmann factor :
rotational energy levelsEnergy
J = 0J = 1
J = 2
J = 3
J = 4
E = 0 1 level E = 2 B 3 levels
E = 6 B 5 levels
E = 12 B 7 levels
J = 5 E = 30 B 11 levels
E = 20 B 9 levels
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o • Several of the lowest energy levels are occupied at room temperature
o Indeed, differentiation of the above equation for N ( J ) with respect to J shows that
the most populated J level corresponds to:
• Hence we will observe a series of spectral lines if we do microwave spectroscopy, at
energies corresponding to:
o ΔE (J ↔ J+1) = 2B(J+1)
o Measurement enables parameter B to be determined
o Extremely accurate method of measuring moment of inertias (and thus bond
lengths) of gaseous molecules.
• Because the upper rotational levels are occupied, we can measure microwave emission
spectra from remote objects:
o Method for identifying molecules in planetary atmospheres
o Method for estimated temperature of remote objects, as the intensity distribution
of the lines in the spectrum depends on temperature.
• For non-rigid molecules (i.e. real ones!):
o Analysis is similar to above, but it is found that bond lengths increase very
slightly the faster the molecule rotate, meaning the apparent value of B decreases
slightly as J goes up.
5.2 Infrared spectroscopy revisited: vibrational-rotational spectroscopy
• Vibrations and rotations can be treated as being independent of each other as they occur
on different timescales.
• For a diatomic molecule, the selection rule is:
Δv = 0, ±1 (for SHO) and Δ J = ±1 and molecule needs a permanent dipole moment
• Thus pure rotational spectra may be observed, but pure vibrational spectraare forbidden despite our discussion in Section 4!
o Each transition from vibrational level v = 0 to v = 1 has to be accompanied by
a rotational change Δ J = ±1 in order to conserve angular momentum.
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o For instance, from the v = 0 J = 3 level we get:
• This means infrared transitions of diatomic molecules actually obey:
o Δ E = hν0 ± 2 B( J +1) J = 0,1,2,3,… (up to the last thermally populated J
level)
o We thus expect to get a series of peaks on either side of ν0
• For gas-phase samples, this so-called “rotational fine structure” is often
observed when recording infrared spectra.
Energy
J = 0J = 1
J = 2
J = 3
J = 4
J = 5
J = 1
J = 2
J = 3
J = 4
J = 5
J = 0
v = 1
vibrational
level
v = 0
vibrationallevel
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• Example 1: here is the background spectrum of air in an IR spectrometer. Note:
o The baseline is not flat
o Lots of rotational fine structure on the water vibrational modes
o Some evidence of fine structure on the CO2 asymmetric stretch
Example 2: IR spectrum of gases in a plume from a volcanic eruption: remote measurement
is possible using the sun as the source of infrared light. [Spectrum from Love et al., OSA
topical conference, 1991]
• For liquid samples, intermolecular collisions usually mean that the linewidths aretoo broad to see rotational fine structure in infrared spectra.
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5.3 Energy diagram for a diatomic molecule
r
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6 Nuclear magnetic resonance (NMR) spectroscopy
• This is usually the “best” method for the structural identification of organic
molecules.
• The sample normally needs to be a liquid.
o Where possible, dissolve solids to make a solution before doing NMR
spectroscopy.
o Far more limited information can be obtained on solids (or gases).
6.1 Simplified background theory
• In the same way that an electron has angular momentum (described by “spin”), nuclei
may also possess angular momentum and so be described as having spin.
o The nuclear spin quantum number, I , gives the total angular momentum.
• The value of I for a particular nucleus depends on the detailed arrangement of protons and neutrons within the nucleus.
o 1H has I = 1/2 2H (0.015% natural abundance) has I = 1
o 12C has I = 0 13C (1.1% natural abundance) has I = 1/2
o 16O has I = 0 17O (0.04% natural abundance) has I = 5/2
• The z-component of nuclear angular momentum is given by the quantum number mI,
which can take values I , I –1, ..., – I .• Ordinarily the mI quantum levels all have the same energy (i.e. are degenerate).
• However they will split into 2 I +1 different energies if a large magnetic field B0 is applied.
• Transitions between these energy levels is termed nuclear magnetic resonance (NMR)
spectroscopy. The selection rule is mI=±1.
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• We shall concentrate only on the case of nuclei having I = ½, the most important of which
are 1H and 13C.
o Nuclei with I = 0 will not show NMR spectra.
o Nuclei with I > ½ tend to give broad uninformative spectral lines.
• The separation of the two energy levels for a spin I = ½ nucleus is given by:
Δ E = (h/2π ) γ B0 (1– σ )
o h = Planck’s constant
o γ = magnetogyric ratio of the nucleus (ratio of magnetic moment to angular
momentum):
For 1H: γ = 26.752 x 107 rad T –1 s –1
For 13C: γ = 6.7283 x 107 rad T –1 s –1
Example:
an I =1
/2 nucleus
No magnetic
field
Sample in strong
magnetic field B0
Energy
Δ E = (h/2π ) γ B0 (1– σ )
mI = – 1/2
mI = 1/2
mI = – 3/2
Energy
Increasing B0
Example:
an I = 3/2 nucleus
4 degenerate levels
when B0 = 0
mI = 3/2
Δ E = hν
mI = – 1/2
mI = 1/2
Δ E = hν
Δ E = hν
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o B0 is the strength of the applied magnetic field (SI unit = Tesla)
o σ is a very small “shielding” term which will depend on the precise
chemical environment of the nucleus under investigation.
• The separation between the energy levels is far smaller than the other techniques
discussed so far.
o We need to use large B0 values to get a measureable population difference
between levels; it turns out NMR signal intensity is proportional to B02.
o Modern NMR spectrometers in research laboratories employ superconducting
magnets:
Typical field strength is 4.7-9.4 Tesla, corresponding to a 1H
resonance frequencies of 200-400 MHz.
Highest available field strength is 21.1 Tesla, corresponding to a 1H
resonance frequency of 900 MHz.
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• The exact separation of energy levels for a nucleus in a molecule depends slightly on its
chemical environment because of the σ shielding term:
o Electrons immediately surrounding the nucleus will tend to circulate in a
particular direction in the applied magnetic field.
o This circulation induces a very small magnetic field δ B at the nucleus which
opposes the large applied magnetic field.
o The result is that the nucleus actually experiencing a magnetic field B0 (1– σ )
• There are also some other effects that cause chemical environment to give a σ
shielding term that we don’t have time to discuss (e.g. hydrogens attached to
aromatic rings have less shielding than might be expected).
• Hence nuclei in different chemical environments in the molecule will have peaks at
different frequencies in the NMR spectrum.
o Those with fewer electrons around them will have less σ shielding.
• The peaks in NMR spectra are usually quoted using the “chemical shift”
scale in parts per million (ppm).o This is effectively a dimensionless frequency scale relative to a standard reference
substance:
o The reference sample for both 1H and 13C NMR spectra is a compound known as
TMS, tetramethylsilane, Si(CH3)4,
o The chemical shift scale is used because it is independent of B0 value –
this is helpful because B0 is rarely known exactly as it changes slightly day by dayfor a superconducting magnet.
e –
B0
δ B
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6.21H NMR spectroscopy
• Peaks in 1H NMR spectra are quantitative – i.e. their area is proportional to
the number of hydrogens in that chemical environment in the molecule.
• Example: low resolution NMR spectrum of ethyl acetate (CH3COOCH2CH3)
• High-resolution 1H NMR spectra show an important additional effect called spin-spin coupling, or alternatively J-coupling.
o The quantum state of a 1H spin is slightly affected by the spin states of hydrogen
nuclei that aren’t chemically equivalent to it, provided that they are within 3 bonds
of it.
• Example 1:
o Consider nucleus HA:
Spin HB may be in the same or the opposite direction to it.
Hence HA sites in a sample have two slightly different energy states.
o NMR signal from HA will therefore be a 1:1 doublet due to coupling to HB.
o Similarly, the NMR signal from HB will be a 1:1 doublet due to coupling to HA.
← chemical shift, δ
← frequency, ν
→ shielding, σ
J /Hz J /Hz
δ /ppm HA HB
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• Example 2:
o Nucleus HA can now couple to two chemically equivalent HB nuclei:
Both HB spins may be in same direction as HA (probability ¼).
Both HB spins may be in opposite direction as HA (probability ¼).
One HB may be in same direction as HA, and one opposite (probability ½).
o NMR signal from HA will therefore be a 1:2:1 triplet due to coupling to HB.
o Note that one HB nucleus does not couple to the other HB nucleus because they are
in chemically equivalent environments.
o The NMR signal from HB will therefore be a 1:1 doublet due to coupling to HA
• Example 3:
o Nucleus HA now can couple to three chemically equivalent HB nuclei.
o The resulting pattern for HA will be a 1:3:3:1 quartet (reflecting the probabilities
of the different possible spin states), while the signal from HB will be a 1:1
doublet due to coupling to HA.
J
J /Hz
δ /ppm HA HB
J J
J
δ /ppm HA HB
J
J /Hz
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• Expert NMR spectroscopists are able to predict J values for different functional groups
and molecular conformations.
o Values are normally in the range 1-12 Hz for a 3 bond coupling.
• Example: high-resolution spectrum of ethyl acetate at a medium magnetic field ( 1H
frequency 100 MHz)
• Example: high-resolution spectrum of ethyl acetate at a high magnetic field
(1H frequency 500 MHz)
• Timescale for 1H NMR experiment is ~1 minute, but setting up may take more time
depending on the experiment being performed.
• Each chemically distinct environment gives rise to a chemical shift (fixed in ppm), which
may then split up due to J-coupling (fixed in Hz).
• Peak areas give relative amounts of each H environment.
500 Hz
7 Hz
100 Hz
7 Hz
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• Functional groups can be identified (via chemical shifts and intensities).
• Linkages between functional groups can be identified (via J-coupling).
• NMR experts are good at identifying molecules from chemical shift and J-coupling
patterns.
• Nowadays, identification of unknown molecules is often by comparison with:
o Established databases of NMR spectra
o The results of computer programs that predict NMR spectra.
• For very large molecules (even proteins!), there are huge numbers of spectral lines:
o NMR techniques have been developed that allow assignment of these, e.g. 2-
dimensional and 3-dimensional spectra reduce overlap between peaks.
Example 1H NMR spectrum: vitamin K1 (C31H46O2) (1H frequency 400 MHz)
(from http://riodb01.ibase.aist.go.jp/sdbs/)
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6.313
C NMR spectroscopy
• The first use of 13C NMR spectroscopy is to give the number of chemically inequivalent
carbon atoms in the sample.
• Note that symmetry considerations may mean that this is less than the
number of carbon atoms in the molecule.
3 carbons 5 carbons 4 carbons
(2:2:4) (2:2:2:1:1) (2:2:2:2)
• The actual 13C chemical shifts provide structural information. For example:
o C=O carbonyl 160-220 ppm
o C=C alkene/aromatic 100-150 ppm
o Saturated C alkyl 10-50 ppm
• As chemical shifts are affected by the shielding given by the surrounding electrons,
substituents have an inductive effect. For example:
o C–OH 50-80 ppm (compared to 10-50 ppm without OH group)• Identification of structural groups is therefore possible:
o By comparison with chemical shift values in reference books
o By comparison with databases of 13C NMR data
o By comparison with results of NMR prediction programs
• J-Coupling to other nuclear spins is possible:
o Probability of 13C of interest being bonded to another 13C nucleus is small (as the
natural abundance of 13C is only 1.1%)
o Coupling to 13C of interest to any 1H bonded to it will happen – this will result in a
splitting up of each 13C peak according to how many hydrogens are directly
bonded to the carbon.
o J-coupling values in this case are ~120 Hz.
o 13C multiplets due to coupling to 1H are:
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• 13C NMR spectra take a long time to acquire if good signal-to-noise is desired (timescale
is hours per spectrum).
• It’s therefore common to record the spectrum using a technique called continuousproton decoupling:
o Almost all 13C NMR spectra are recorded this way
o This eliminates the J-coupling to H nuclei, and so concentrates multiplet signal
intensities into a single peak
o The sample is irradiated with a broad bandwidth pulse whilst the 13C NMR
spectrum is recorded such that all protons rapidly cycle between their spin up and
spin down states, so that they become decoupled from 13C.
o Coupling to protons other than that of H can still take place.
o The result is a significant saving in the time it takes to record the spectrum.
However, doing the experiment in this way means that the 13C NMR
spectra don’t have absolutely reliable relative intensities.
Example 13C NMR spectrum (proton decoupled): riboflavin (vitamin B2, C17H20 N4O6)
(from http://riodb01.ibase.aist.go.jp/sdbs/)
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6.4 Industrial on-line NMR spectroscopy
• The NMR techniques described above are those used in research and specialist analytical
laboratories.
• They can’t be implemented on a chemical plant: they’re too expensive and the hardware
is not robust enough.
• There’s also a problem measuring NMR spectra of flowing samples – the nuclei under
investigation need to be in the magnet for a certain length of time before they can be
measured by NMR.
o Slow flow only, or need to “stop” the flow for the measurement.
• On a chemical plant, we can use permanent magnets of far lower magnetic field strength
(corresponding to a 1H frequency of, say, 20 MHz)
o Can’t do high-resolution spectroscopy but can sometimes separate low-resolution
signals: for instance, we can get a measurement of the ratio of aromatic to
aliphatic 1H environments in gasoline.
o 1H NMR signal intensity can be used to estimate the water content in solids.
o 1H NMR relaxation times (how long spins take to move from the upper energy
level to the lower energy level) of liquids in porous solids gives some information
on the pore sizes present; this is used in oil-well logging.
• Magnetic resonance imaging (MRI) is also being developed for use in a process plant
setting.
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7 Methods of elemental analysis
• In this section, three principal methods of elemental analysis are described.
• They aren’t the only methods for doing elemental analysis:
o For example, titration, gravimetry, and electrochemical measurements can also be
used.
7.1 CHN Analysis
• Organic compounds are normally analysed by flash combustion of a small
sample (typically 1-2 mg) in oxygen – unlike spectroscopic techniques, this is destructive
test.
• An exact amount of sample is weighed inside a small tin capsule.
• The capsule is introduced into the analyser’s furnace which is at 950°C.
• The tin capsule combusts, elevating the temperature to >1800°C.
• At this temperature, the sample is vaporised and forms CO2, H2O and a mixture of N2,
NO, NO2.
C xH y N z O + O2 → xCO2 + y/2 H2O + z NO2 + O2
• The product gases are then analysed:
o Instruments differ on whether they try to remove SOx, halogens, phosphorus etc.
before analysing the product gases, or whether they try to measure them.o The product gases are normally reduced (using copper at high temperature)
to remove O2 and convert NOx gases to N2 before analysis.
o Some instruments separate the product gases:
This can be by using chromatography (see Section 9), or by having a water
and a CO2 trap (using Mg(ClO4)2 and NaOH respectively).
A thermal conductivity detector is normally used to measure the gas
concentrations.
o A few instruments use infrared spectroscopy of the mixture as the detectiontechnique.
• From the product gas concentration, the original mass fractions of C, H, and N in the
sample are calculated.
• With modern CHN analysers:
o Little attention is required by operator, other than a daily calibration of instrument.
o Analysis is complete in 15 minutes.
• Oxygen contents of the sample can only be obtained indirectly using this method (e.g. by
comparing the sample mass used, and that calculated for C+H+N components).
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o For a direct measurement of oxygen, pyrolysis (=heating in absence of air) in the
presence of platinum-carbon can be used: this gives CO, which is then converted
to CO2 and detected quantitatively.
7.2 Atomic spectroscopy
• Atomic absorption spectroscopy (AAS) is a very sensitive method
for detecting the presence and concentration of about 70 elements.
• A sample of solution is vaporized to its constituent atoms in a hot flame.
• A hollow cathode lamp containing the element under investigation emits lights at specific
frequencies for that element.
• The photons will be absorbed by the sample if the frequencies correspond to an allowed
transition of atoms in the flame.
o Recall selection rule for transitions of electrons between atomic orbitals is:
Δn = anything ; Δl = ±1 ; Δml = 0, ±1
• The absorbance obeys the Beer-Lambert law to a good approximation, and so
concentrations can be determined quantitatively.
• In practice the spectrometer will be calibrated on solutions of known concentration
beforehand to achieve high accuracy.
• Advantages of AAS:
o Sensitivity to a wide range of elements (typically down to 1 ppm)
o High accuracy if care is taken over sample preparation and calibration.
• Disadvantages of AAS:
o Some solid samples are difficult to get into solution form.
o Need a hollow cathode lamp for sharp monochromatic lines for each element.
o Different atoms require different flame temperatures to achieve reliable results(e.g. air/acetylene 2250°C; NO/acetylene 2955°C).
Light at ν
(chosen for specific
element of interest) Measure absorptionF
L
A
M
E
Atomic orbitals
hν
Solution of sample
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o Other factors influencing absorption may need to be taken into account:
excited states of the atom under investigation (e.g. ionisation of Na/K)
potential interferences from other elements present.
• Atomic emission spectroscopy (AES) is a similar process:
o Again a solution of sample is introduced into a hot flame.
o This time the intensity of a particular frequency emitted is measured.
o The advantage here is that there is no need for individual lamps for each element.
o The disadvantage is that it is far less sensitive than AAS.
• Inductively Coupled Plasma (ICP) spectrometers use a plasma
(temperature >7000 K) rather than a flame:
o Under these conditions, atomic emission spectra (ICP-AES) can be measured with
similar sensitivity to AAS, while removing many of the chemical interferences
present in a flame.
o Mass spectrometry (ICP-MS) may be used to measure mass of atoms/ions present
in the plasma directly using a quadrupole mass spectrometer [see Section 8].
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7.3 X-ray fluorescence (XRF)
• This is a method of elemental analysis for solid samples. It’s useful for those that don’t
easily dissolve, e.g. some minerals and ores.
• X-rays are fired at the sample, and these knock out a core electron from an inner quantum
level (e.g. from the 1s, 2s or 2p atomic orbital).
• An electron then falls from an upper energy level to fill the core-level vacancy; this is
accompanied by the emission of a photon of frequency hν.
• The wavelengths of emitted photons enable the elements present in the sample to be
determined, while the intensities give the amount of each element present (after careful
calibration).
• This method is only appropriate for elements with atomic numbers greater
than ~20. Gram quantities of a solid sample are required.
1s
2s
2p
3s
3p3d
4s4p
hν
Hole created
by X-rays
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8 Mass spectrometry (MS)
• Mass spectrometry is a widely used technique in analytical chemistry
o It can measure the molecular weight of components present in a sample
o It can identify particular chemicals
o After calibration, it can be used quantitatively.
• All mass spectrometers involve the following steps:
o Production of ions in the gas phase
o Separation of the ions according to their mass-to-charge (m/ z ) ratio.
o Detection of ions
• There are several different ways of performing each step.
8.1 Production of ions: five methods
• Electron Ionisation (EI) is the most common method of ionisation for small organic
molecules:
o The sample must first be vaporized (by heat or a spark) if it isn’t already in gas
phase.
Some sample decomposition may occur for thermally unstable samples
during this step.o The sample is then bombarded with electrons that knock an electron out:
M + e – → M+ + 2e –
o The parent ion is always produced in a vibrationally excited state and so might
fragment (often in a fairly predictable manner) to smaller ions before it reaches
the detector.
o EI is a harsh ionisation method: fragmentation may be so extensive that the parent
ion is absent from the spectrum.
o The fragmentation pattern provides a fingerprint method of sampleidentification by comparison of results with MS databases.
o Example: EI MS of vinyl chloride
[Figure from //www.cem.msu.edu/~reusch/VirtualText/Spectrpy/MassSpec/]
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• Chemical Ionisation (CI) is a common alternative ionisation approach for
small organic molecules:
o Again, the sample is first be vaporized (by heat or a spark)
o A small amount of methane is present in the ionisation chamber, which is ionised
by electron impact.
o This then reacts to form species such as CH5+ that can donate H+ to the sample of
interest:
CH4 + e – → CH4+ + 2e –
CH4+ + CH4 → CH5
+ + CH3
M + CH5+ → MH+ + CH4
o Ionisation of M to give MH+ by this method is thus by proton transfer.
o This is a “softer” method of ionisation than EI, so less fragmentation occurs.
o The parent ion [MH]+ is likely to be the most prominent peak; note that it will be
at a molecular weight one greater than that of molecule M.
o If the methane concentration is too high, then sometimes the species [MC2H9]+ is
detected as well.
• Fast-Atom-Bombardment (FAB) may be used to ionise medium-sized
organic molecules:
o High-energy atoms hitting the sample can vaporise and ionise it in the same step
Since no heating is required, this method can be used to analyse samplesthat aren’t thermally stable.
o The parent ion [MH]+ is normally detected together with some useful
fragmentation.
o The method works for quite large molecules (up to about 5000 Da).
• For very large macromolecules such as proteins, the above methods don’t work well:
o multiple fragmentation makes interpretation difficult/impossible.
o it’s difficult to separate species with high m/ z ratios (e.g. above 5000 Da).
• Electrospray ionisation (ESI) has now become common for MS of
proteins:
o A solution of the sample passes through a metal capillary that has a high applied
voltage, and is then sprayed out to produce droplets (10 µm) with a very high
charge.
o The droplets shrink as the solvent evaporates, so Coulombic repulsion between the
charges increases until it causes each droplet to break up into smaller droplets.
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o Continuing the shrinking/breaking up process eventually leads to the molecule of
interest being a lone ion – it may be singly or multiply charged.
o This is a very soft method of ionisation, and so negligible fragmentation occurs.
o For proteins, the method produces a range of ions, e.g. from [MH10]10+ to
[MH20]20+
o Example: ESI MS of myoglobin (mass 16955 Da).
[Figure from http://www.chm.bris.ac.uk/ms/theory/]
• Matrix-Assisted Laser Desorption Ionisation (MALDI) is another ionisation method
used for very large molecules:
o The sample is dispersed in a solid matrix to form a solid solution.
o A laser is then used to disintegrate the solid solution – the matrix material is
chosen so that it absorbs the laser wavelength.
o Clusters ejected from the surface break up to give the sample molecule in [MH]+
or [MNa]+ form; some are multiply charged ions.
o There is little fragmentation using this technique.
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8.2 Analysis and detection of ions: three methods
• Once the ions have been formed, we need to separate them according to m/ z ratio.
• This part of the spectrometer will need to be at a good vacuum because we don’t want the
ions to hit other molecules before reaching the detector.
• The analysis method used will depend on mass resolution required, mass range, scan rate,
and detection limit required.
• Magnetic-sector instruments: this is the “traditional” method, but is now
becoming rarer.
o These accelerate ions through a voltage V and then deflect them by a magnetic
field ( B) through a radius of curvature r .
o Only ions of correct mass-to-charge ratio (m/ z ) will reach the detector:
o Scanning either the magnetic field or the accelerating voltage produces a
spectrum.
[from http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/MassSpec/masspec1.htm#ms1]
• Time-of-flight (TOF) method:
o The ions are accelerated through a voltage (V ) and the time taken for them to
travel a specific distance to reach the detector is measured.
o The kinetic energy that each ion has is given by:
o Hence ions of low m/ z will have large v and reach the detector first.
o TOF instruments are usually very sensitive, and can scan a large mass range.
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• Quadrupole detectors:
o The ions pass through an area with four hyperbolic magnetic poles created by a
radiofrequency field.
o Only certain ions can take a stable path through the field and be detected.
o Scanning the rf field (by increasing voltage) allows a mass spectrum to be quickly
and easily recorded, but resolution is more limited than the other methods.
8.3 Uses of MS
• Low-resolution mass spectrometry gives integer masses for peaks:
o Useful for structural identification
• High-resolution mass spectrometry can be very accurate:
o It can distinguish between CO, N2 and C2H4; these have exact molecular weights
of 27.9949, 28.0062 and 28.0313 mass units respectively.
o Even more useful for structural identification.
• For small organic molecules, the fragmentation pattern in EI MS often provides structural
information:
o For instance a peak at M+ –16 may correspond to loss of –NH2 suggesting an acid
amide to be present.o Fragmentation can permit identification of compounds by comparison with
database of known mass spectra.
• The different isotopes of the elements are very important in MS:
o For instance, molecules containing a single chlorine atom will give separate MS
peaks for the 35Cl and 37Cl isotopes (in a relative ratio of ~3:1)
o The natural abundance of 13C is 1.1%; MS peaks due to ions with one (or more)13C isotope in them will be observed, particularly for medium and large
molecules.• MS is used sometimes “on-line” in the process industries:
o Quadrupole detectors aren’t too expensive and are fairly robust
o The most common use is for analysis of gas-phase species; only difficulty is
reducing pressure from process operating conditions to good vacuum inside
instrument.
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9 Chromatography
• All the techniques discussed so far are limited in one important respect:
o They can only easily analyse pure compounds, or simple mixtures at best.
• What do we do if the sample is a complicated mixture?
• Chromatography is the key separation technique used by analytical chemists when
the sample is a mixture.
• After calibration, chromatography can be used for structural identification and
quantitative measurement as well as simply being a separation technique.
• Chromatography is also a chemical engineering unit operation for purification of high-
value chemicals, particularly in the pharmaceutical and biotechnology industries.
• Chromatography is based on the physical separation of individual chemical components
in a sample:
o The sample is present in a mobile or carrier phase: may be gas, liquid, or even
supercritical fluid.
o The sample is separated into components due to differences in affinity for a
stationary phase.
9.1 Gas chromatography (GC)
• For GC, the carrier phase is an inert gas (e.g. He, Ar, N 2).
• The sample needs to be vaporised if it’s not already a gas, and injected as a pulse into the
carrier stream.
• The stationary phase is usually a column containing the stationary phase on a fused silica
support:
o The column is usually very narrow (say 2 mm diameter) and may be 1-10 m long;
physically it will look like a coiled loop.
o There are many types of silica and modified silica so different separations can beachieved.
• Separation is based on the components having different retention times on the column:
o affected by boiling points of the substances to be separated.
o affected by selective adsorption of a component onto the stationary phase.
• The column is located in an oven, the temperature of which can be controlled.
• For good separations in a reasonable length of time, it’s common for the temperature of
the oven to be increased over the course of the experiment.
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• GC experimental configuration:
[from http://teaching.shu.ac.uk/hwb/chemistry/tutorials/chrom/gaschrm.htm]
• There are a range of detectors available. We’ll mention the two most common.
• Flame ionisation detectors (FID):
o These are widely used for analysis of organic compounds.
o Gas at the column exit is mixed with hydrogen and air and burnt. Any organic
compounds present produce ions and electrons in the flame making it capable of
conducting electricity. The FID measures the current response to an electric
potential at the burner tip.
o The FID response has high sensitivity, a large linear response range, and low
noise. It is also robust and easy to use, but it destroys the sample.
o For hydrocarbons, the FID peak areas are proportional to the number of carbon
atoms present in that component of the sample.
• Thermal conductivity detectors (TCD):
o These compare the thermal conductivity of the gas at the column exit with a
reference flow of carrier gas (usually He). Any change is due to the presence of
sample compounds.
o Disadvantage: TCDs are slightly less sensitive than FIDs and have slightly lower
resolution (as they have a larger dead volume).
o Advantage: TCDs can be used to detect any compound (i.e. not just
hydrocarbons), and the sample isn’t destroyed.
o Because the thermal conductivity of organic compounds tend to be similar to each
other, TCD peak areas for hydrocarbons are roughly proportional to the
concentration of that component.
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• Example: GC of a mixture of air + 9 hydrocarbons:
(a) column at 45°C – separate components 1-5; don’t get components 6-9.
(b) column at 145°C – doesn’t separate 1-4; does separate components 5-8.
(c) column heated a linear rate from 30-200°C – separates components 1-9. There’s also less “band spreading”
as a function of time.
From http://www.uft.uni-bremen.de/chemie/pdf/GC_Intro_Christian_Jungnickel.pdf
45°C
145°C
time,min
time,min
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9.2 Liquid chromatography (LC)
• Note modern instruments often use the acronym HPLC (for “high-performance” or
“high-pressure” LC).
• In this case the sample is in the liquid phase (by dissolving into solution if it’s not already
a liquid).
• The stationary phase is a solid packed into a column; it can be a liquid-coated solid.
• Different detector systems are used (e.g. UV, fluorescence, refractometry).
• A variety of different separation mechanisms are used.
• Liquid-Solid separations are based on the intermolecular interactions between sample
molecules and the solid phase.
o For instance, these may be polar interactions or hydrogen bonding
interactions.
o The “normal” case is that the solid has hydroxyl groups at the surface and so has
an affinity for polar groups: Less polar molecules will pass through the column faster than polar
molecules if the surface of the solid likes polar species.
o In “reverse phase” chromatography, the stationary phase is made hydrophobic
(e.g. silica with n-alkyl chains covalently bound to its surface):
In this case, hydrophobic compounds will have longer retention times than
hydrophilic ones.
o The retention times are critically affected by the polarity of the solvent (carrier
phase).
T ramp:
30-200°C
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Mixtures that don’t separate when using one solvent as carrier phase may
separate easily using a solvent of different polarity.
o This technique is widely used in synthetic organic chemistry labs as a bench-scale
purification technique.
• Liquid-Liquid separations are based on the partition of the sample between two liquid
phases.
• Size-Exclusion chromatography is based on the molecular size of the compounds
present.
o The stationary phase consists of solid beads containing small pores.
o Large compounds can’t enter inside the beads and thus will elute first.
o Smaller compounds enter the beads and will have longer retention times.
• Ion-exchange chromatography operates on the basis of selective exchange of ions
in the sample with those in the stationary phase.
Carrier solvent
Inject
sample
Packed
column
Carrier solvent Carrier solvent Carrier solvent
Collect
product 1
12
3
1
2
3
1
2
3
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o The column consists of a polymer matrix bearing certain ionic functional groups:
e.g. M–SO3 – H+ for the case of cation exchange (anion exchange columns
also exist).
o Molecules capable of ion-exchange will be retained at these sites :
e.g. if they contain cations or acidic hydrogens in this example.
o Molecules retained on the column can be subsequently collected by changing the
properties of the mobile phase:
e.g. by changing the pH so that the carrier liquid will displace sample
molecules attached to the column.
• Affinity chromatography uses immobilized biochemicals that have a
specific affinity to the compound of interest.
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9.4 Hyphenated techniques
• These are simply a combination of the techniques that we’ve discussed so far.
• Examples include:
o GC – MS
o LC – MS
o LC – NMR
• With these techniques, separation and sample identification of complex mixtures can be
performed in a single piece of equipment.
• This represents the “state of the art” in modern analytical chemistry.