High Performance Liquid Chromatography (HPLC) PDF

Summary

This document provides an overview of high-performance liquid chromatography (HPLC). It explains the importance of HPLC in various applications and discusses factors such as particle size, column pressure, and mobile phase composition. The document is focused on HPLC principles and practices in chemical analysis and other applications involving chromatography.

Full Transcript

4/25/2020

Chapter 24

- Diffusion in liquids is 100 times slower than diffusion in gases. So it is not generally
feasible to use open tubular columns in liquid chromatography

• The efficiency of a packed column increases as the size of the
stationary phase particles decreases.
• Typical particle sizes in HPLC are 1.7 to 5 mm.
• Smaller particles in packed column
• Decreased Plate height H
increased resolution

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Decreasing particle size
permits us to improve resolution or to maintain the same resolution
while decreasing run time.
(a and b) Chromatograms of
the same sample run at the same linear
velocity on 5.0-cm-long columns packed with
C18-silica.

Plate number increased from 2000 (a) to
7500 (c) when the particle size decreased, so the peaks are
sharper with the smaller particle size

At the optimum flow rate for each column
(minimum plate height in Figure 24-3), the
number of theoretical plates in a column of
length L (cm) is approximately

dp is the particle diameter in mm.
The 5.0-cm-long column in Figure 24-2a with 4.0-mm-diameter particles is
predicted to provide N of ~ (3 000)(5.0)/4.0=3800 plates. (The observed
plate number for the second peak is 2 000. Perhaps the column was not run
at optimum flow rate).
When the stationary phase particle diameter is reduced to 1.7 mm, the
optimum plate number is expected to be ~(3 000)(5.0)/1.7 = 8 800. The
observed value is 7500.

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Why small particles give better resolution ?
1) Small particles provide more uniform flow through the column, thereby reducing the multiple path term,
A, in the van Deemter equation.
2) The distance through which solute must diffuse in the mobile and stationary phases depends on the
particle size. The smaller the particles, the less distance solute must diffuse. This effect decreases the
C term in the van Deemter equation for finite equilibration time. Or equilibration time is achieved faster

Smaller particle size leads to
• higher plate number (better resolution)
• higher pressure (because of particle resistrance)
• shorter optimum run time
• lower detection limit (because small particle size with narrow columns and high flow rate, analyte is
not diluted so much as it travels through the column)

Column Pressure
The penalty for small particle size is resistance to solvent flow. The pressure required to
drive solvent through a column is

where ux is linear flow rate, h is the viscosity of the solvent, L is the length of the column, r is column radius,
and dp is the particle diameter. The factor f depends on particle shape and particle packing.

From the above equation, the pressure in HPLC is proportional to the flow rate and column length
But inversely proportional to the square of column radius (or diameter) and the square of particle diameter.

Another penalty of small particle size is the increased frictional heating as solvent is forced through the particles.
The center of a column is warmer than the outer wall, and the outlet is warmer than the inlet.

To avoid band broadening from temperature differences, column diameter should be ≤ 2.1 mm for 1.7-mm particles

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Columns are expensive and easily degraded by dust or particles or impurities.
To avoid introducing particulate matter into the column, samples should be centrifuged or
filtered through a 0.5-mm filter before they are loaded into vials for an auto-sampler or
injected manually.
Structure
1. Guard column: Protect the main column
• it has the same stationary phase of main column (usually 1 cm long)
• It adsorb strongly Fine particles and irreversible adsorbed solutes.
• periodically replaced after a set number of injections or time in service.
1. Main column: steel or plastic
5–30 cm long
inner diameter 1–5 mm
Titanium frits contain the stationary phase
uniform flow between narrow tubing and the column

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Effect of raised temperature:
1. Decreases retention times and improves resolution because of decreased viscosity of solvent and solutes.
2. increased temperature can degrade the stationary phase and decrease column lifetime.
3. Can also degrade the analyte or the solvent used.
To reduce temperature effect, use narrow column and small amount of analyte.

Bare silica can be used in adsorption chromatography
Bonded stationary phase on silica is used in liquid-liquid partition chromatography
• pure, spherical microporous silica: most common support
permeable to solvent
• has a surface area of several hundred square meters per gram.
• Silica cannot be used above pH 8, because it dissolves in base.

Bare silica (a) : A silica surface has up to 8 mmol of silanol groups (Si-OH) per square meter.
Silanol groups are protonated at pH < 2–3 and dissociate to negative Si-O- ap H > 3.

Silica with ethylene bridges resist
hydrolysis up to pH 12.

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Tailing of amine silica on bases
Bare silica (a) : Si-O- (at pH > 3) retain
strongly protonated bases (RNH3+) and
lead to tailing. Metallic impurities in
Type (a) silica also cause tailing.

(b) Less acidic Type (b) silica with
fewer Si-OH groups and less
metallic impurity gives
Symmetric peaks with shorter
retention time

Bonded stationary phase is covalently bonded to silica surface

Used for liquid-liquid
partition chromatography

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The siloxane (Si-O-Si-R) bond hydrolyzes below pH 2,
so HPLC with a bonded phase on a silica support is generally
limited to the pH range 2–8.

If bulky isobutyl groups are
attached to the silicon atom of
the bonded phase, the stationary
phase is protected from attack
by H3O+ and is stable for long
periods at low pH, even at
elevated temperature

Another type of nonpolar stationary phase has
a polar embedded group such as polar
amide group.
Embedded polar groups provide alternate
selectivities from C18 stationary phases,
Improved peak shapes for bases, and
compatibility with 100% aqueous phase.

Other nonpolar stationary
phases should not be exposed to100%
aqueous phase because they become very
difficult to re-equilibrate with organic phase.

Nonpolar bonded phase with embedded
polar amide group offers different selectivity
from C18, has improved peak shape for bases,
and tolerates 100% aqueous eluent.

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Superficially Porous Particles
Also called fused-core particles
-It consist of a 0.25-mm-thick porous
silica layer on a 5-mm diameter
nonporous silica core.

-A stationary phase such as C18 is
bonded throughout the thin porous
outer layer.
-Mass transfer of solute into a 0.25-mmthick layer is 10 times faster than mass
transfer into a 2.5 mm fully porous silica

-SPP are especially suitable for separation
of macromolecules such as proteins, which
diffuse more slowly than small molecules.

The Elution process
In adsorption chromatography, solvent
molecules compete with solute molecules
for adsorption sites on the stationary phase
The relative abilities of the different solvents
to elute a given solute is mostly related to
the elution strength of the eluents

Elution occurs when solvent displace solutes
from the stationary phase (competition
between solute and solvent).

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The Elution process

In normal-phase chromatography (bare silica):
we use
a polar stationary phase
a less polar solvent (or non aqueous solvent).
A more polar solvent has a higher eluent strength.
Reversed-phase chromatography
nonpolar or weakly polar stationary phase
the solvent is more polar (or aqueous).
A less polar solvent has a higher eluent strength.
More common

In general, eluent strength is increased by making the mobile phase more like the
stationary phase.

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But if one solvent does not provide sufficiently rapid elution of all components, we use gradient elution

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Isocratic HPLC Separation

Separation becomes better
as B decreases, however, it
takes much longer time

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Isocratic HPLC Separation

Separation becomes much
better as B decreases,
however, it takes too long

Gradient Elution
Start with Low B% and then
increase B% gradually

Result :
Good separation and shorter
time

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Hydrophilic Interaction Chromatography
( or Hydrophilic Interaction liquid Chromatography (HILIC)

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