Sna thin layer chromatography

Thin Layer Chromatography
• Thin layer chromatography (TLC) is
a chromatographic technique used to separate
the components of a mixture using a thin
stationary phase supported by an inert
backing. It may be performed on the analytical
scale as a means of monitoring the progress of
a reaction, or on the preparative scale to
purify small amounts of a compound.

Thin Layer Chromatography
• TLC is an analytical tool widely used because
of its simplicity, relative low cost, high
sensitivity, and speed of separation.TLC
functions on the same principle as all
chromatography: a compound will have
different affinities for the mobile and
stationary phases, and this affects the speed
at which it migrates. The goal of TLC is to
obtain well defined, well separated spots.

Retention Factor
• After a separation is complete, individual
compounds appear as spots separated
vertically.
• Each spot has a retention factor (Rf) which is
equal to the distance migrated over the total
distance covered by the solvent.

Retention Factor
• The Rf formula is
• Rf=distance traveled by sample distance traveled
by solvent
• The Rf value can be used to identify compounds
due to their uniqueness to each compound.
• When comparing two different compounds under
the same conditions, the compound with the
larger Rf value is less polar because it does not
stick to the stationary phase as long as the polar
compound, which would have a lower Rf value

Retention Factor
• Rf values and reproducibility can be affected
by a number of different factors such as layer
thickness, moisture on the TLC plate, vessel
saturation, temperature, depth of mobile
phase, nature of the TLC plate, sample size,
and solvent parameters. These effects
normally cause an increase in Rf values.
However, in the case of layer thickness,
the Rf value would decrease because the
mobile phase moves slower up the plate.

Retention Factor
• If it is desired to express positions relative to
the position of another substance, x,
the Rx (relative retention value) can be
calculated:
• Rx=distance of compound from origin distance
of compound x from origin
• Rx can be greater than 1.

Apparatus-Plates
• As stated earlier, TLC plates (also known as
chromatoplates) can be prepared in the lab,
but are most commonly purchased.
• Silica gel and alumina are among the most
common stationary phases, but others are
available as well.

Apparatus-Plates
• Many plates incorporate a compound which
fluoresces under short-wave UV (254 nm). The
backing of TLC plates is often composed of
glass, aluminum, or plastic.
• Glass plates are chemically inert and best
withstand reactive stains and heat, but are
brittle and can be difficult to cut.

Apparatus-Plates
• Aluminum and plastic plates can be cut with
scissors, but aluminum may not withstand
strongly acidic or oxidizing stains, and plastic
does not withstand the high heat required to
develop many stains.
• Aluminum and plastic plates are also flexible,
which may result in flaking of the stationary
phase.

Apparatus - Plates
• Never under any circumstances touch the face
of a TLC plate with your fingers as
contamination from skin oils or residues on
gloves can obscure results. Instead, always
handle them by the edges, or with forceps.

Apparatus - Plates
• The properties of your sample should be
considered when selecting the stationary
phase.
• As shown below in Table 1, silica gel can be
exclusively used for amino acids and
hydrocarbons.
• It is also important to note that silica gel is
acidic.

Apparatus - Plates
• Therefore, silica gel offers poor separation of
basic samples and can cause a deterioration of
acid-labile molecules.
• This would be true for alumina plates in acidic
solutions as well.
• It is important to note that there are
differences between silica gel and alumina.

Apparatus - Plates
• Alumina is basic and it will not separate
sample sizes as large as silica gel would at a
given layer thickness.
• Also, alumina is more chemically reactive than
silica gel and as a result, would require more
care of compounds and compound classes.
• This care would avoid decomposition and
rearrangement of the sample.

Table 1: Stationary phase and mode of separation1
Stationary Phase
Chromatographic Mechanism Typical Application
Silica Gel adsorption
steroids, amino acids, alcohols,
hydrocarbons, lipids, aflaxtoxin,
bile, acids, vitamins, alkaloids
Silica Gel RP reversed phase
fatty acids, vitamins, steroids,
hormones, carotenoids
Cellulose, kieselguhr partition
carbohydrates, sugars, alcohols,
amino acids, carboxylic acids, fatty
acids
Aluminum oxide adsorption
amines, alcohols, steroids, lipids,
aflatoxins, bile acids, vitamins,
alkaloids
PEI cellulose ion exchange
nucleic acids, nucleotides,
nucelosides, purines, pyrimidines
Magnesium silicate adsorption
steroids, pesticides, lipids,
alkaloids

Solvent
• Proper solvent selection is perhaps the most
important aspect of TLC, and determining the
best solvent may require a degree of trial and
error.
• As with plate selection, keep in mind the
chemical properties of the analytes.
• A common starting solvent is 1:1 hexane:ethyl
acetate.
• Varying the ratio can have a pronounced effect of
Rf. Rf values range from 0 to 1--0 means that
the solvent polarity is very low and 1 means the
solvent polarity is very high.

Solvent
• When performing your experiment, you do
not want your values to be 0 or 1 because
your components that you are separating have
different polarities.
• If the value is 0, you need to increase your
solvent polarity because the sample is not
moving and sticking to the stationary phase.
• If the value is 1, you need to decrease your
solvent polarity because the compound was
not able to separate.

Solvent
• If you know that one component of a mixture
is insoluble in a given solvent, but another
component is freely soluble in it, it often gives
good separations.

Solvent
How fast the compounds travel up the plate
depends on two things:
• If the compound is soluble in the solvent, it
will travel further up the TLC plate
• How well the compound likes the stationary
phase. If the compound likes the stationary
phase, it will stick to it, which will cause it to
not move very far on the chromatogram.
You should be able to determine which by
looking at the Rf value.

Solvent
• Acids, bases, and strongly polar compounds
often produce streaks rather than spots in
neutral solvents.
• Streaks make it difficult to calculate an Rf and
may occlude other spots. Adding a few
percent of acetic or formic acid to the solvent
can correct streaking with acids.
• Similarly for bases, adding a few percent
triethylamine can improve results. For polar
compounds adding a few percent methanol
can also improve results.

Solvent
• The volatility of solvents should also be
considered when chemical stains are to be
used.
• Any solvent left on the plate may react with
the stain and conceal spots.
• Many solvents can be removed by allowing
them to sit on the bench for a few minutes,
but very nonvolatile solvents may require time
in a vacuum chamber.
• Volatile solvents should only be used once. If
the mobile phase is used repeatedly, results
will not be consistent or reproducible.

Useful Solvent Mixtures
• A solvent which can be used for separating
mixtures of strongly polar compounds is ethyl
acetate : butanol : acetic acid : water,
80:10:5:5.
• To separate strongly basic components, make
a mixture of 10% NH4OH in methanol, and
then make a 1 to 10% mixture of this in
dichlormethane.
• Mixtures of 10% methanol or less in DCM can
be useful for separating polar compounds.

Pipettes
• Spots are applied to the plate using very thin
glass pipettes. The capillary should be thin
enough to apply a neat spot, but not so thin as
to prevent the uptake of an adequate quantity
of analyte. Here is a popular method of
producing TLC pipettes.
• Heat a glass capillary in the very tip of a
Bunsen burner flame just until it becomes
pliable and then pull the ends apart until the
center of the capillary is significantly narrower.
Snap this in half and use the thin end to apply
spots.

Spotting and Developing
• Developing a TLC plate requires a developing
chamber or vessel.
• This can be as simple as a wide-mouth jar, but
more specialized pieces of glassware to
accommodate large plates are available.
• The chamber should contain enough solvent to
just cover the bottom.
• It should also contain a piece of filter paper, or
other absorbent material to saturate the
atmosphere with solvent vapors. Finally, it should
have a lid or other covering to minimize
evaporation.

1
• Cut the plate to the correct size and using a pencil
(never ever use a pen), gently draw a straight line
across the plate approximately 1 cm from the bottom.
• Do not use excessive forces when writing on a TLC
plate as this will remove the stationary phase.
• It is important to use a pencil rather than a pen
because inks commonly travel up the plate with the
solvent.
• An example of how black ink separates is shown in the
section labeled "examples".

2
• Using TLC pipettes, apply spots of analyte to the
line.
• Make sure enough sample is spotted on the
plate.
• This can be done by using the short-wave UV.
• A purple spot should be seen.
• If the spot is not visible, more sample needs to be
applied to the plate.
• If a standard of the target compound is available,
it is good practice to produce a co-spot by
spotting the standard onto a spot of the unknown
mixture.
• This ensures the identity of the target compound.

3
• Place the plate into the chamber as evenly as
possible and lean it against the side.
• Never allow the bulk solvent to rise above the
line you drew.
• Allow capillary action to draw the solvent up
the plate until it is approximately 1 cm from
the end.
• Never allow the solvent to migrate all the way
to the end of the plate.

4
• Remove the plate and immediately draw a
pencil line across the solvent front.
5
• Use a short-wave UV light and circle the
components shown with a pencil.

An example is shown below:
Figure 1: TLC Sequence

Below is a TLC plate under UV light:
Figure 2: TLC plate under UV light.

Visualizing
• If fluorescent plates are used, a number of
compounds can be seen by illuminating the plate
with short-wave UV.
• Quenching causes dark spots on the surface of
the plate. These dark patches should be circled
with a pencil.
• For compounds which are not UV active, a
number of chemical stains can be used. These can
be very general, or they can be specific for a
particular molecule or functional group.

Visualizing
• Iodine is among the most common stains. Plates
are placed in a jar containing iodine crystals, or
covered in silica gel with iodine dispersed
throughout, for approximately one minute.
• Most organic compounds will be temporarily
stained brown.
• Some popular general use stains are
Permanganate, ceric ammonium molybdate
(CAM), and p-anisaldehyde.
• These can be kept in jars which plates are dipped
into, or in spray bottles.

Visualizing
• To develop a plate with permanganate, spray or
dip the plate and heat it with a heat-gun. Hold
the plate face up 10 to 20 cm above the heat gun
until the bulk water evaporates.
• Then move the plate to 5 to 10 cm above the
heat gun and heat it until white/yellow/brown
spots appear. Overheating will turn the entire
plate brown, obscuring the spots.
• If glass plates are used it is often easier to see
spots through the backing because it is harder to
overheat.

Visualizing
• CAM and p-anisaldehyde stained plates are
developed similarly. Overheating CAM stained
plates turns everything blue. Attached is a pdf
of common stains for use in TLC, what the
stains are good for and how to make them

Advantages of TLC
• TLC is very simple to use and inexpensive.
Undergraduates can be taught this technique and
apply its similar principles to other
chromatographic techniques.
• There are little materials needed for TLC
(chamber,watch glass, capillary, plate, solvent,
pencil, and UV-light).
• Therefore, once the best solvent is found, it can
be applied to other techniques such as High
performance liquid chromatography.

Advantages of TLC
• More than 1 compound can be separated on a
TLC plate as long as the mobile phase is
preferred for each compound.
• The solvents for the TLC plate can be changed
easily and it is possible to use several different
solvents depending on your desired results.

Advantages of TLC
• As stated earlier, TLC can be used to ensure
purity of a compound. It is very easy to check
the purity using a UV-light. Identification of
most compounds can be done simply by
checking Rf literature values. You can modify
the chromatography conditions easily to
increase the optimization for resolution of a
specific component.

Disadvantages of TLC
• TLC plates do not have long stationary phases.
Therefore, the length of separation is limited
compared to other chromatographic techniques.
Also, the detection limit is a lot higher.
• If you would need a lower detection limit, one
would have to use other chromatographic
techniques.
• TLC operates as an open system, so factors such
as humidity and temperature can be
consequences to the results of your
chromatogram.

Common Problems in TLC
• There are common problems in TLC that
should be avoided.
• Normally, these problems can be solved or
avoided if taught proper techniques.

Over-large Spots:
• Spotting sizes of your sample should be not be
larger than 1-2 mm in diameter.
• The component spots will never be larger than
or smaller than your sample origin spot.
• If you have an over-large spot, this could
cause overlapping of other component spots
with similar Rf values on your TLC plate.
• If overlapping occurs, it would prove difficult
to resolve the different components

Uneven Advance of Solvent Front:
• Uneven advance of the mobile phase is a
common problem encountered in TLC.
Consequences would be inaccurate Rf values
due to the uneven advance of sample origin
spots. This uneven advance can be caused by
a few factors listed below.

• No flat bottom. When placing the TLC plate
into the chamber, place the bottom of the
plate on the edge of the chamber (normally
glass container (e.g. beaker)) and lean the top
of the plate along the other side of the
chamber. Also, make sure that the TLC plate is
placed in the chamber evenly. Do not tilt the
plate or sit it at an angle.

• Not enough solvent. There should be enough
solvent (depends on size of chamber) to travel up
the length of the TLC plate.
• Plate is not cut evenly. It is recommended that a
ruler is used so that the plate is cut evenly.
Rarely, water is used as a solvent because it
produces an uneven curve front which is mainly
accounted for by its surface tension.

Streaking:
• If the sample spot is too concentrated, the substance
will travel up the stationary phase as a streak rather
than a single separated spot.
• In other words, the solvent can not handle the
concentrated sample and in result, moves as much of
the substance as it can up the stationary phase.
• The substance that it can not move is left behind. This
can be eliminated by diluting the sample solution.
• To ensure that you have enough solution, use a short-
wave UV light to see if the spot is visible (normally
purple in color), as stated earlier.

Spotting:
• The sample should be above the solvent
level. If the solvent level covers the sample,
the sample spot will be washed off into
the solvent before it travels up the TLC plate.
An example is shown below:

Examples
• Below are TLC plates to help show how
samples separate.
• These images are chromatograms of black ink
.

Figure 3: Chromatogram of TLC plate

Figure 4: Chromatogram of 10 essential oils

Sna thin layer chromatography

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