Introduction to Modern Liquid Chromatography, Third Edition part 32 pptx

Although improvements in resolution may be explored by changing the B-solvent solvent-type selectivity, the new mobile phase must have a similar solvent strength in order to maintain com

mobile phases will often provide a better separation This proved to be the case for

the present sample A 1:1 blend of the mobile phases of Figure 6.8a (46% ACN) and Figure 6.9a (61% MeOH) was prepared, and used to obtain the separation of Figure 6.9b The new mobile phase (containing 23% ACN+ 30% MeOH) provides

baseline resolution (R s = 1.8).

(a)

(b)

S

“regular”

r 2 = 1.00

6

4

2

0

log k w

2

1

0

%B (100f)

Figure6.7 Variation of log k with %B for regular and irregular samples (a) Regular sample (a

mixture of herbicides [24]), separated on a C18column with methanol-water as mobile phase

(see Fig 2.6 for other conditions); (b) plot of values of S versus log k w for data of (a); (c) irreg-ular sample of Figure 6.6; conditions as in Figure 6.6; (d) plot of values of S versus log k wfor

data of (c) (a, b) Adapted from [25].

4.0

3.5

3.0

2.5

2.0 S

log k w

“irregular”

r2 = 0.87

(c)

%B (100 f)

2.0

1.5

1.0

0.5

0.0

1 2 3 4

5 6 7 8

Figure6.7 (Continued)

While the separation of Figure 6.9b is much improved, further variation in the proportions of mobile phase from Figure 6.8a (46% ACN) and Figure 6.9a (61% MeOH) may provide some more resolution Peaks 1 to 4 in Figure 6.9b are less

resolved than remaining peaks 5 to 10 (i.e., peaks 1–4 are ‘‘critical’’), so we will

limit our discussion to these peaks Figures 6.10a–c replicate earlier chromatograms

for peaks 1 to 4 from Figures 6.8 and 6.9, for changes in the relative proportions

of ACN and MeOH As MeOH replaces ACN in going from Figure 6.10a–c, it

is seen that peaks 2 and 3 (shaded) move toward the front of the chromatogram

In Figure 6.10b (1:1 blend of mobile phases from Fig 6.10a,c), the critical (least

resolved) peak-pair is 2/3, and we can improve its resolution by a further movement

0 2 4 6 8 10 12 14

Time (min)

1 2

3 + 4

5

10 6

(a)

46% ACN

1.1≤ k ≤ 4.6

R s= 0.0

Time (min)

1

2 + 3 + 4

5

(b)

34% ACN

2≤ k ≤ 14

R s= 0.3

Figure6.8 Separation of a mixture of substituted benzenes as a function of solvent

strength (%B) Sample: 1, p-cresol; 2, benzonitrile; 3, 2-chloroaniline; 4, 2-ethylaniline; 5, 3,4-dichloroaniline; 6, 2-nitrotoluene; 7, 3-nitrotoluene; 8, toluene; 9, 3-nitro-o-xylene; 10, 4-nitro-m-xylene Conditions: 250 × 4.6-mm (5-μm) C8column; acetonitrile–pH-6.5 buffer mobile phase; 35◦C; 1.0 mL/min Chromatograms recreated from data of [26] Note that all compounds are non-ionized under these condition, so the sample is effectively neutral

Time (min)

1 2

3

4

5

(b)

30% MeOH + 23% ACN

1≤ k ≤ 4

R s= 1.8

Time (min)

1 2 3

4

5

(a)

61% MeOH

0.8≤ k ≤ 3.0

R s= 0.6

Figure6.9 Solvent-type selectivity Separation of a mixture of substituted benzenes with methanol or mixtures of methanol-acetonitrile as mobile phase Same sample and conditions

as in Figure 6.8, except as noted in figure Chromatograms recreated from data of [26]

of peak 2 away from peak 3 and toward peak 1 This can be achieved by increasing the proportion of MeOH in the final mobile phase (with respect to the mobile

phase of Fig 6.10b) As seen in Figure 6.10d, a mixture of 57% Figure 6.10c (61% MeOH) and 43% Figure 6.10a (46% ACN) positions peak 2 midway between peaks

1 and 3 for maximum resolution (R s = 2.0 vs R s = 1.8 in Fig 6.10b) Achieving

an optimum final separation in this example involves simple interpolation between

4 6

Time (min)

1

3

(c)

61% MeOH

0.8≤ k ≤ 3.0

R s= 0.6

6 Time (min)

1

2

3

4

(d)

57/43 mixture of (c) and (a)

1≤ k ≤ 4

R s= 2.0

(a)

46% ACN

1.1≤ k ≤ 4.6

R s= 0.0

Time (min)

1

2

3 + 4

6 Time (min)

(b)

50/50 mixture of (a) and (c)

(30% MeOH + 23% ACN)

1≤ k ≤ 4

2

3

4

Figure6.10 Solvent-type selectivity: fine-tuning the B-solvent Same sample and conditions as

in Figures 6.8 and 6.9 (peaks 1–4 only), plus added figure (d); (b) is 30% MeOH+ 23% ACN,

and (d) is 35% MeOH+ 20% ACN Chromatograms recreated from data of [26]

the two preceding experiments (Fig 6.10b,c), much like the example of Figure 6.6

where %B was optimized Similar optimizations of selectivity can be carried out more conveniently by the use of computer simulation (Chapter 10)

Although improvements in resolution may be explored by changing the B-solvent (solvent-type selectivity), the new mobile phase must have a similar

solvent strength in order to maintain comparable values of k and run time In Figure 6.9a, a higher %-MeOH was used (61% vs 46% ACN) because methanol is

a weaker (more retentive) B-solvent than acetonitrile When changing solvent type,

we can estimate the necessary change in %B for the new B-solvent by means of the

solvent nomograph of Figure 6.11 Here similar %B values for different B-solvents

fall on vertical lines Recall that in the previous example we needed to replace 46% ACN with a similar strength MeOH-water mobile phase From the diagram of Figure 6.11, we see that 46% ACN should be about equivalent in strength to 57% MeOH (each of these two mobile phases is marked by•in Fig 6.11); this is close to

the mobile phase actually selected in Figure 6.9a (61% MeOH) Note that the run time in Figure 6.9a (11 min) is somewhat shorter than that in Figure 6.8a (15 min),

0 10 20 30 40 50 60 70 80 90

0 20 30 40 50 60 70 80 90

THF/H2O MeOH/H2O

ACN/H2O

Figure6.11 Solvent-strength nomograph for reversed-phase HPLC (adapted from [28]) Two mobile phases of equal strength (46% ACN and 57% MeOH) marked by•, as an example

as could be expected from Figure 6.11; that is, 61% MeOH is stronger than the 57% MeOH recommended by Figure 6.11

To summarize, when using a change in solvent type to change selectivity and

increase resolution, proceed as follows: If ACN was used in the initial separation, and

MeOH is to be substituted, Figure 6.11 shows how to estimate the best %-MeOH for use in the second separation Next examine the ACN and MeOH chromatograms to determine if a mixture of ACN and MeOH is likely to give a better separation than

either B-solvent alone (as in Fig 6.9b) Conditions can be improved as illustrated

by Figure 6.10 and discussed further in Section 6.4.1 If MeOH was used initially

as the B-solvent, use Figure 6.11 to estimate the equivalent % ACN for a change in B-solvent without affecting the solvent strength

Solvent-type selectivity arises from interactions among solute, B-solvent, and column, as described in Sections 2.3.2.1 and 5.4.1 The preferential retention of the B-solvent in the stationary phase means that a stronger interaction of the

B-solvent and solute will normally lead to increased retention (this may at first seem counterintuitive, in terms of the discussion of Fig 2.7a,b) However, even qualitative

predictions of the effect of a given B-solvent on the relative retention of different solute classes (e.g., phenols, ethers) are difficult at best For further discussion, see [23]

6.3.3 Temperature Selectivity

Retention as a function of temperature can usually be described by

log k = A + B

T K

(6.2)

where A and B are constants for a given compound when only the absolute temperature T K (K) is varied Plots of log k versus 1/T K should therefore yield

straight lines, as in Figure 6.12a for a number of polycyclic aromatic hydrocarbons

(PAHs) An increase in column temperature by 1◦C usually results in a decrease

in values of k by 1–2% for each peak in the chromatogram [29] The effect of

a change in temperature on selectivity is usually minor for the RPC separation of neutral samples However, exceptions have been noted, as in the case of PAHs [30]

and plant pigments [31] Figure 6.12b is an extension of Figure 6.12a, with data for

three additional PAHs (dashed curves A–C); compounds 1 to 6 are flat, fused-ring

0.5

1000/TK

45 °C 35 °C 25 °C 15 °C

6

5

4

3

2

1

A B

C

22 °C

1.0

0.5

1000/TK

45 °C 35 °C 25 °C 15 °C

6

5

4

3

2 1

(a)

(b)

Figure6.12 Retention of polycyclic aromatic hydrocarbons as a function of separation tem-perature Conditions: 250× 4.6-mm (5-μm) Chromegabond-C18column; 80% ACN-water;

1.0 mL/min (a) Sample (fused-ring aromatic hydrocarbons): 1, anthracene; 2, fluoranthene; 3, triphenylene; 4, chrysene; 5, 3,4-benzofluoranthene; 6, 1,2,5,6-dibenzoanthracene (b) Sam-ple same as (a), plus added poly-aryls: A, 1,1,-dinaphthyl; B, 1,3,5-triphenylbenzene; C,

9,10-diphenylanthracene Adapted from [30]

PAHs such as anthracene (peak 1), while compounds A to C are three-dimensional (nonflat) poly-aryls such as 1,1,-dinaphthyl (peak A) It is seen that retention reversals (marked by •) occur in Figure 6.12b for five adjacent peak-pairs as

temperature is varied between 15 and 45◦C (Note the◦C scale at top of figure): B/5

at 42◦C, A/3 at 36◦C, C/6 at 31◦C, B/4 at 16◦C, and C/5 at 6◦C In this example there are major changes in selectivity as temperature is varied As a result several

temperatures exist between 10 and 70◦C where baseline resolution (R s ≥ 1.5) is

possible, for example, a temperature of 22◦C, as shown in Figure 6.12b by a vertical

dotted line

Changes in resolution with temperature for this sample are better seen in the

resolution map of Figure 6.13a: a plot of critical resolution as a function of

temper-ature The resolution map of Figure 6.13a is enhanced in Figure 6.13b, to provide

additional insight into this very useful tool Thus potentially critical peak-pairs (e.g.,

B/4, C/6, A/3) that correspond to different line segments in Figure 6.13a are identified

in Figure 6.13b Similarly arrows in Figure 6.13b indicate four temperatures where baseline resolution (R s ≥ 1.5) is possible Resulting separations for the latter four preferred temperatures are shown in Figures 6.13c–f (note the changed retention

order in each of these examples) The three poly-aryls A–C (shaded peaks) are seen

to be retained more strongly at higher temperatures relative to the fused-ring PAHs 1–6 (see the further discussion of following Section 6.3.3.1) The best separation

(R s = 2.1) is provided by a temperature of 22◦C While changes in temperature sometimes can be effective in altering separation selectivity for neutral samples, changes in selectivity with temperature are much more likely for partly ionized acids

or bases (Section 7.3.2.2) For a further discussion of temperature selectivity in RPC, see [32, 32a]

6.3.3.1 Further Observations

The following treatment provides a more complete picture of temperature selectivity for neutral samples However, the reader may prefer to skip this discussion and continue with Section 6.3.4.

While Equation (6.2) is generally an adequate representation of RPC retention

as a function of temperature, more complex changes in k with temperature are sometimes observed [7, 33–35] Sometimes k increases when the temperature is increased, or plots of log k versus 1/T may be curved instead of linear These

exceptions to Equation (6.2) are often associated with acidic or basic solutes and a mobile phase pH that is close to the pKavalue of the solute (see Section 7.2) In such cases a change in temperature may result in a change in the relative ionization of

an acid or base (Section 7.2.3), with a large resulting change in solute retention—in addition to (and sometimes opposing) the normal effect of temperature that is described by Equation (6.2)

The dependence of log k on temperature is determined by the value of B in

Equation (6.2), which is proportional to the enthalpy of retention, H Values

of B usually increase for larger values of k; as a result plots of log k versus 1/T

for different solutes (other conditions the same) often resemble the fan-shaped

plots of Figure 6.12a for several fused-ring PAHs The latter behavior can be compared with the similar example of Figure 6.7a for regular samples as %B is varied; in both cases (change in %B or T) a change in condition has the largest effect on k for the most retained solute (with the largest values of k) For most

neutral samples, changes in retention order with temperature are not expected

(as observed in Fig 6.12a), but maximum resolution may still be observed at an

intermediate temperature However, a change in temperature is generally less useful for improving the resolution of neutral samples (similar to the case of ‘‘regular’’ samples and solvent-strength selectivity)

As noted in Figure 6.12b, values of B tend to be relatively smaller for more

com-pact molecules such as phenylnaphthalene (a poly-aryl), compared to less comcom-pact molecules such as anthracene (a fused-ring PAH) Similar temperature-selectivity

effects have been observed for gas chromatography [36], where values of B in Equation (6.2) decrease in the order n-alkynes > n-alkanes > branched alkanes

> cycloalkanes That is, values of B in GC also decrease for less extended, more

compact molecule—possibly for similar reasons

6.3.4 Column Selectivity

During the early days of HPLC, a change of column was often used as a means of varying selectivity and improving resolution Indeed column selectivity represents

a powerful means for altering relative retention and improving the separation of neutral samples However, the use of column selectivity alone for the purpose of systematically improving separation has a serious limitation, compared to changes

in %B, solvent type, or temperature When any of the latter conditions are varied,

2.0

1.0

0.0

R s

T (°C)

R s= 1.5 B/4

C/5

A/3

C/6 A/3

B/5

A/4 B/6

2.0

1.0

0.0

R s

T (°C)

(a)

(b)

3/4 A/4

Figure6.13 Separation of polycyclic aromatic hydrocarbons as a function of temperature

Sample and conditions of Figure 6.12 (a, b) resolution map; (c–f ) chromatograms for

differ-ent optimum temperatures Adapted from [30]

0 2 4 6 8 10 12

Time (min) Time (min) Time (min)

Time (min)

T = 11 °C

R s = 1.9

T = 22 °C

R s = 2.1

T = 46 °C

R s = 1.7

T = 61 °C

R s = 1.7

(c)

(d)

(e)

(f)

1

2 A 3

B 4

5

C

6

1

2 A 3

5

1

2

3 A 5

1 2

3

4 A

5

6

4

Figure6.13 (Continued)

continuous changes in selectivity are possible, and there will often be an intermediate

condition that corresponds to maximum resolution In the examples of Figure 6.13, this greatly increased the likelihood of an acceptable separation, compared to the use of only one or two arbitrary temperatures When the column is changed, the selection of an intermediate separation (between that provided by either column) is inconvenient As a result a change in just the column is less likely to result in an improved separation (but see the further discussion of Section 6.4.1.4) Changes in the column are also less convenient than changes in continuous variables

Examples of a change in selectivity when only the column is changed are shown in Figure 6.14 for a 10-component neutral sample and four columns of varying selectivity Despite significant changes in selectivity for this sample when

the column is changed, no single column provides a resolution of R s > 0.8, as long

as other conditions remain fixed (as in this example) If two different columns are connected together, additional separation possibilities are created, but this procedure

Time (min)

Symmetry C18

1.6≤ k ≤ 19, R s= 0.4 1

2 3 4 5 +

(a)

10

1≤ k ≤ 7, R s= 0.4

Alltima HP C18 amide

Time (min)

1 3

2 + 4

6

8

9 + 10

(b)

1≤ k ≤ 11, R s= 0.8

Luna phenyl-hexyl

Time (min)

1

2 3 4

5 6

10 9

(c)

1≤ k ≤ 14, R s= 0.0

Spherisorb ODS-2

Time (min)

2 4

1

8+ 9

10 3

(d)

Figure6.14 Separation of a mixture of 10 organic compounds of diverse structure on four

different columns Sample: 1, 4-nitrophenol; 2, 5,5-diphenylhydantoin; 3, acetophenone; 4, benzonitrile; 5, 5-phenylpentanol; 6, anisole; 7, toluene; 8, cis-chalcone; 9, ethylbenzene; 10, trans-chalcone Conditions: 150 × 4.6-mm (5-μm) columns; 45% acetonitrile-water; 35◦C; 2.0 mL/min Chromatograms recreated from data of [8, 9]

is inconvenient and only marginally better than the use of a single column (in the example of Fig 6.14, no combination of these four columns can improve the

separation of Fig 6.14c) The real advantage of a change in column selectivity is only

achieved when a change in column is accompanied by a simultaneous change in one

or more other conditions, for example, %B, solvent type, and/or temperature for the case of neutral samples (Section 6.4.1.4)