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Lab.2. Thin layer chromatography
Key words:
Separation techniques, compounds and their physicochemical properties (molecular
volume/size, polarity, molecular interactions), mobile phase, stationary phase, liquid
chromatography, thin layer chromatography, column chromatography, retardation factor,
elution, chromatogram development, qualitative and quantitative analysis with
chromatography techniques, eluotropic series, elution strength.
Literature:
D.A. Skoog, F.J. Holler, T.A. Nieman: Principles of Instrumental Analysis; 637 - 718
Search on www pages “Thin-layer chromatography principles”
For example: MIT Digital Lab Techniques Manual you find on
http://www.youtube.com/watch?v=e99nsCAsJrw&feature=player_detailpage
Basic equipment for modern thin layer chromatography:
www.camag.com/downloads/free/brochures/CAMAG-basic-equipment-08.pdf
other examples:
en.wikipedia.org/wiki/Thin_layer_chromatography
www.chemguide.co.uk/analysis/chromatography/thinlayer.html
www.wellesley.edu/Chemistry/chem211lab/Orgo_Lab_Manual/Appendix/Techniques/TLC/th
in_layer_chrom.html
Theoretical background
Chromatography is the separation technique in which separated solutes are distributed
between two phases: stationary and mobile. The first phase can pose a layer of
sorbent/adsorbent (0.1 to 0.25 mm in thickness) fixed to a carrier plate made of glass, plastic
or aluminum (used in technique named as thin-layer chromatography, TLC) or placed inside
of a steel tube as a column bed (used in a technique named as high-performance liquid
chromatography, HPLC, or generally in column liquid chromatography, LC). The second
phase, mentioned above, constitute liquid or gas phase. Various organic (e.g. methanol,
hexane, acetone) and inorganic (e.g. water) solvents or their mixtures (e.g. acetone and
Lab.2. Thin layer chromatography
hexane, methanol and water) can be used as the mobile phases. So each chromatographic
system consists of:
a) stationary phase,
b) mobile phase,
c) mixture of components to be separated.
A solution of the component mixture is usually introduced into the chromatographic system
by injection (in HPLC or classical column chromatography in entrance to the column) or by
spotting/application onto start line (in TLC). In column chromatography the mobile phase is
pumped through the adsorbent bed or its flow is caused by gravitation as it is demonstrated in
Fig 1A. In thin layer chromatography mobile phase is driven into movement by capillary
forces (solvent wets adsorbent layer on the chromatographic plate by capillary forces) as it is
demonstrated in Fig 1B. Under such circumstances mixture components migrate along the
stationary phase (adsorbent) according to the direction of flow of the mobile phase.
Mobile
phase
A B
Station
ary
phase
Chromatographic
plate
Valve
Chromatographic
chamber
Mobile
phase
Fig. 1. (A) Classical column chromatography, (B) chromatogram development in
conventional chamber (in cuboid vessel)
Migration velocities of mixture components are slower from that o the mobile phase. It is
because of time, which separated molecules spend in the stationary phase. Arrangement of
solute zones on the chromatographic plate after chromatogram development is demonstrated
in Fig. 2.
Lab.2. Thin layer chromatography
Solvent front
Start line
Fig. 2. Thin layer chromatogram of dyes, 1 and 10 – dye mixture, 2 – 9 single dyes
The time the separated molecules spend in the stationary phase depends on their interactions
with stationary and mobile phases. It means the mixture components can be separated in the
chromatographic system if they demonstrate different migration distances, i.e. if they show
different energy of molecular interactions with components of the chromatographic system.
Following molecular interactions of solutes with elements of stationary and mobile phases can
take place in any chromatographic system: hydrogen bond, dipole – dipole, dipole – induced
dipole, ion – dipole, instantaneous dipole – induced dipole (London dispersion forces), ion –
ion.
The stationary phase
1. Silica gel
Silica gel is composed of silicon dioxide (silica). The silicon atoms are bonded via oxygen
atoms in a giant covalent structure. However, at the surface of the silica gel -OH groups are
attached to the silicon atoms. So, on the surface of silica gel Si-O-H groups are present
instead of Si-O-Si ones. This makes silica surface very polar.
Fig. 3 shows the model of a small part of the silica surface.
Lab.2. Thin layer chromatography
Fig.3. A simplified model of silica gel surface
There are also silica based adsorbents, which are non-polar, i.e. chemically modified silica.
Modified silica gel is formed by chemical reaction of its surface with e.g.
trichlorooctadecylsilane or other reagents. Thus the surface polarity decreases and then its
hydrophobicity increases.
2. Aluminum oxide
Aluminum oxide (Al O ) is another adsorbent, which is often used as stationary phase in
2 3
laboratory practice. TLC aluminum oxide plates usually comprise neutral or basic aluminum
oxide. These kinds of plates provide distinct separation features with regard to a pH range of
the mobile phase used. Under aqueous conditions basic compounds can be well separated
with basic aluminum oxide plates, while neutral compounds can be successfully separated
with neutral aluminum oxide ones.
3. Cellulose
Cellulose is the next adsorbent used as a stationary phase in chromatography systems,
especially in TLC. Macromolecules consisting of D-glucose units coupled -glycosidically at
positions 1 and 4 by oxygen atoms stand for this adsorbent. A section of a cellulose chain is
shown in Fig. 4.
Fig. 4. Fragment of cellulose macromolecule
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