Chromatographic Separations

Chromatographic Separations

Introduction & Basics

Read all of Skoog – Chapter 26.



Common analytical problem: identify and quantify >1 component

in a mixture.



Ideally

 Completely selective method to analyze each component

individually in the mixture

 In absence of such a method, separate the analyte(s) prior to

analysis to avoid selectivity issues



Separations Methods

 Distillation

 Extraction

 Chromatography

 Electrophoresis



Introduction to separations: liquid-liquid extraction

The solute = S is partitioned between 2 liquid phases Φ1 and Φ2







Equilibrium constant or

Partition coefficient or

Distribution constant K = [S]2/[S]1









1

So what gives a better separation of solute between the 2 phases –

1 large extraction or several small ones?



Solute A has K = 3 between toluene and water ([A] in toluene = 3x

[A] in water). Start with 100 mL of 0.01 M aqueous solution of A

and extract with toluene. Which procedure gives a better

extraction:

a) 1 extraction with 500 mL toluene

or

b) 5 extractions with 100 mL toluene/extraction









2

The more equilibria a mixture attains between 2 different phases

the greater the separation.



Instrumental separations methods (i.e. chromatography) designed

to give the maximum number of equilibria (theoretical plates).



Chromatography operates on the same principle as extraction, but

one phase is held in place (stationary phase) while the other moves

past it (mobile phase).



The interaction of the solute with the stationary phase to a large

extent dictates the distribution constant K. The nature of this

interaction is one way to generally categorize chromatographic

methods. For a solute A: K = [A]stat Φ/[A]mobile Φ









3

The basics remain the same regardless of the type of interaction

dictating the distribution constant.



Note that your text in Table 26-1 also categorizes chromatographic

methods by the type of mobile phase:

 GC = gas chromatography, gaseous mobile phase

 LC = liquid chromatography, liquid mobile phase

 SFC = supercritical fluid chromatography, supercritical fluid

mobile phase



Below, 2 substances A and B are shown eluting down a column

packed with stationary phase. Mobile phase is continuously added

such that elution continues until the substances are eluted from the

end of the column.









If K = [A]stat Φ/[A]mobile Φ

 Then K for solute A 20 then tR is too long causing various problems





Ideally k’ between 1 and 10, separation conditions are

adjusted to make that happen (discussed in Ch 26, Section D)







Now the last definition: selectivity factor. The point of

chromatography is to effect a separation, which is

fundamentally based on differences in partition coefficients

between solutes.



α = KA/KB = selectivity factor

(α > 1 by definition)









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Two factors contribute to how well compounds are separated:

1. Difference in elution times between peaks: (already)

explained by equilibrium theory. Larger difference in K, the

better the separation.

2. The wider the peaks, the poorer the separation. Now to be

treated by rate theory.



Band broadening and column efficiency: Rate theory Section 26C



Chromatography peaks are Gaussian.



Overall uncertainty = ∑ many random uncertainties

Most common result = mean

Width defined by standard deviation



In previous section we looked at the average result (mean = tR)

In this section better to think at the molecular level

and remember…

A solute can only move down the column while in the mobile

phase





A single solute molecule may get “hung up” in the stationary phase

and lag behind,

Or

A single solute molecule may spend an inordinate amount of time

in the mobile phase and race ahead.



The result: band broadening.









8

Early on chromatography and band spreading was treated as an

equilibrium process using distillation theory. Terminology, which

can cause confusion, unfortunately remains.



Theoretical Plate – where a solute undergoes equilibrium between

mobile and stationary phase.



Number of theoretical plates = N

Plate Height = H









If N = L/H and H = s2/L









9

w2 = 16s2; s2 = w2/16





At a given mobile phase flow rate L is proportional to tR for a

given solute so:







A solute with a retention time of 407s has a width at the base of

13s, on a 12.2m long column. Find N and H.









Column separation efficiency increases as N increases, and

increases as H decreases.



Compare N and H only for the same compound.

Chromatography: N = 100 – 10,000

H = 0.1 – 0.001 cm

Capillary electrophoresis: N ~ 106

H ~ 10-3 cm

So far, column efficiency discussed by plate or equilibrium theory,

which cannot explain the following experimental data:









10

The above van Deemter plot shows that there is an optimum flow

rate, and that plate height is very much a function of mobile phase

flow velocity.



What are the mechanisms for zone broadening?



H = A + B/u + Cu

van Deemter equation









The multipath (A) term





11

The longitudinal diffusion (B/u) term









Mobile and stationary phase mass transfer (Cu) term









Breaking the van Deemter plot into individual contributors:





12

Comparison of van Deemter plots for gas chromatography (GC)

and liquid chromatography (LC)









 At low flow rates plate height decreases with increasing flow

rates from longitudinal diffusion term. Larger effect in GC







 For same reason plate heights smaller in LC than GC.





The multipath A term:



13

A = 0 for no packing (common in GC, not LC)



Summary

 Addressed migration rates and distribution constants (26B)

 Addressed zone broadening (26C)



Now – optimization of column performance (26D) by either

 Altering relative migration rates, or

 reducing zone broadening



The goal is to resolve 2 or more solutes in a mixture – dependent

on differences in retention time and zone width.



Resolution Rs = ΔtR/Wav









14

A little algebra to derive relationships relating resolution, retention

times (i.e. retention and selectivity factors), and zone broadening

(i.e. theoretical plates).









15

Note that the above equation can be rearranged to find N for a

desired resolution:





In practical terms, resolution is only important when KA≈KB









Example 26-1 on p. 777 reviews many concepts.



The fundamental parameters of selectivity (α), retention factor (k)

and theoretical plates (N,H) can all be varied to achieve a

separation.



Selectivity:



Theoretical Plates/Plate Height:



Retention factor: easiest way to improve resolution









16

A more general discussion…









Gradient Elution in liquid chromatography – a systematic variation

of mobile phase composition to optimize k for a wide range of

solutes.



Temperature programming in gas chromatography – a systematic

variation of temperature to optimize k for a wide range of solutes.









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General applications of chromatography (Section 26F)



Qualitative analysis

 tR only qualitative information. No structural information.

Strong indicator of presence of analyte, unequivocal proof of

analyte absence.

 Useful for separation prior to acquiring structural information

using another technique which would not be useful for a

mixture.



Quantitative analysis

 Peak areas

 Reproducible injection volumes (calibrations)





End of Chapter 26 questions/problems:

1-3, 6-15, 17-19, 21









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