The van Deemter equation in chromatography, named for Jan van Deemter, relates the variance per unit length of a separation column to the linear mobile phase velocity by considering physical, kinetic, and thermodynamic properties of a separation.[1] These properties include pathways within the column, diffusion (axial and longitudinal), and mass transfer kinetics between stationary and mobile phases. In liquid chromatography, the mobile phase velocity is taken as the exit velocity, that is, the ratio of the flow rate in ml/second to the cross-sectional area of the ‘column-exit flow path.’ For a packed column, the cross-sectional area of the column exit flow path is usually taken as 0.6 times the cross-sectional area of the column. Alternatively, the linear velocity can be taken as the ratio of the column length to the dead time. If the mobile phase is a gas, then the pressure correction must be applied. The variance per unit length of the column is taken as the ratio of the column length to the column efficiency in theoretical plates. The van Deemter equation is a hyperbolic function that predicts that there is an optimum velocity at which there will be the minimum variance per unit column length and, thence, a maximum efficiency. The van Deemter equation was the result of the first application of rate theory to the chromatography elution process.
The van Deemter equation relates height equivalent to a theoretical plate (HETP) of a chromatographic column to the various flow and kinetic parameters which cause peak broadening, as follows:
HETP=A+
B | |
u |
+(Cs+Cm) ⋅ u
Where
In open tubular capillaries, the A term will be zero as the lack of packing means channeling does not occur. In packed columns, however, multiple distinct routes ("channels") exist through the column packing, which results in band spreading. In the latter case, A will not be zero.
The form of the Van Deemter equation is such that HETP achieves a minimum value at a particular flow velocity. At this flow rate, the resolving power of the column is maximized, although in practice, the elution time is likely to be impractical. Differentiating the van Deemter equation with respect to velocity, setting the resulting expression equal to zero, and solving for the optimum velocity yields the following:
u=\sqrt{
B | |
C |
The plate height given as:
H=
L | |
N |
with
L
N
tR
\sigma
In this case the plate count is given by:
N=\left(
tR | |
\sigma |
\right)2
W1/2
N=8ln(2) ⋅ \left(
tR | |
W1/2 |
\right)2
or with the width at the base of the peak:
N=16 ⋅ \left(
tR | |
Wbase |
\right)2
The Van Deemter equation can be further expanded to:[2]
H=2λdp+{2\gammaDm\overu}+{\omega(dpor
2 | |
d | |
c) |
u\overDm}+{Rd
2 | |
f |
u\overDs}
Where:
The Rodrigues equation, named for Alírio Rodrigues, is an extension of the Van Deemter equation used to describe the efficiency of a bed of permeable (large-pore) particles.[3]
The equation is:
HETP=A+
B | |
u |
+C ⋅ f(λ) ⋅ u
where
f(λ)=
3 | |
λ |
\left[
1 | |
\tanh(λ) |
-
1 | |
λ |
\right]
and
λ