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Gas Chromatography of Organochlorine Compounds

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    154230
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    Learning Outcomes

    At the end of this assignment, students will be able to:

    • Identify what characteristics of a gas chromatographic stationary phase determine the retention times for and extent of separation between injected compounds.
    • Discuss the parameters used to evaluate the quality of a separation in GC.
    • Understand why temperature programming is used in GC and what determines the maximum operating temperature of a column.
    • Explain the figures of merit important in evaluating the performance of a gas chromatographic column.

    Purpose

    The purpose of this assignment is to introduce concepts of gas chromatography (GC) as they pertain to the separation and identification of organochlorine pesticides found in water samples.

    Organochlorine compounds can be quantitatively determined by gas chromatography (GC) at very low levels. The chromatographic column is chosen to separate a large number of the organochlorine species through differential retention by the stationary phase. Separation can be enhanced by temperature programming of the column during separation. Although this project focuses on GC-MS, detection for gas chromatography of organochlorines is also commonly accomplished by electron capture detection (ECD).

    Sources of information about compounds and the physicochemical properties affecting their separation can be found at:

    NIST Webbook: http://webbook.nist.gov/chemistry/

    NIH Chem IDPlus chem.sis.nlm.nih.gov/chemidplus

    Compound Separation in Gas Chromatography

    The most common columns used today are long (e.g., 30 or 60 m) fused silica capillary tubes. The stationary phase typically consists of a polymeric liquid that is first coated onto and then chemically bonded to the underlying glass surface of the capillary tube. The stationary phase is chosen for its interaction with the compounds to be separated and for its stability to heat. As a compound in the gas phase moves through the column encountering the bonded phase, it will spend some amount of time partitioned into the bonded phase due to an interaction with that material. The magnitude of a compound’s interaction with the stationary phase is expressed as a partition coefficient. Compounds must have different partition coefficients to be separated by a chromatographic column. The smaller the partition coefficient, the less time the compound spends within the stationary phase and the faster it elutes from the column.

    Once a stationary phase has been selected, it is important to be able to predict the elution order (the order in which compounds will emerge from the column) of the chemical compounds we wish to separate. In gas chromatography, one possibility is to consider the differences in the boiling points of compounds. The boiling point of a pure compound is dependent on the intermolecular interactions between the molecules. The stronger these interactions, the higher the boiling point. Boiling points of linear alkanes are primarily controlled by dispersion forces. The more atoms in the alkane, the greater the number of polarizable electrons, the greater the energy of interaction, and, consequently, the higher will be the boiling point of the alkane. Table 1 gives the boiling points of a series of linear alkanes

    Table 1. Linear Alkane Data (http://webbook.nist.gov/chemistry/)

    Compounds

    # C atoms

    Mass

    Boiling Point oC

    Boiling Point K

    Propane

    3

    44.0956

    -42.0oC

    231.1

    Butane

    4

    58.122

    -0.5

    272.5

    Pentane

    5

    72.148

    36.0

    309.2

    Hexane

    6

    86.17

    68.8

    341.9

    Heptane

    7

    100.2

    98.4

    371.5

    Octane

    8

    114.22

    125.6

    398.7

    Nonane

    9

    128.255

    150.6

    423.8

    Decane

    10

    142.28

    174.0

    447.2

    Undecane

    11

    156.3083

    195

    468

    n-dodecane

    12

    170.3348

    216

    489

    Tridecane

    13

    184.3614

    234

    507

    Tetradecane

    14

    198.3880

    250

    523

    Pentadecane

    15

    212.4146

    267

    540


    Q1. Using the data in Table 1, create a graph of the boiling points of this series of linear alkanes as a function of mass. Describe the trend you observe in the graph.

    Q2. Figure 1 contains a portion of chromatogram showing the elution of a sample of n-alkanes from a column held at a constant temperature of 87oC. Estimate the approximate time at which C16 will appear?

    Fig1.png

    Figure 1. Separation of n-alkanes using hydrogen as the carrier gas. http://www.restek.com/

    Table 2. Structures, molecular weights, boiling points and retention times of selected organochlorine pesticides (NIST, CHEM IDplus).

    Compound

    Formula CAS registry

    Structure

    M.W. g/mol

    B.P. oC

    Retention time (min) tablulated using 8081B column DB-608

    1) Alpha-Lindane (HCH)

    C6H6Cl6

    319-84-6

    Alpha-Lindane.png

    290.8280

    288

    8.14

    2) Del-lindane (HCH)

    C6H6Cl6

    319-86-8

    Alpha-Lindane.png

    290.8280

    11.20

    3) Gamma lindane (HCH)

    C6H6Cl6

    55963-79-6

    Gamma lindane.png

    290.8280

    323.4

    9.52

    4) Lindane

    C6H6Cl6

    58-89-9

    Lindane.png

    290.8280

    323.4

    5) 4-4' DDE

    C14H8Cl4

    72-55-9

    4-4' DDE.png

    318.0241

    336

    16.34

    6) 4-4'-DDD

    C14H10Cl4

    72-54-8

    4-4'-DDD.png

    320.0400

    350

    18.43

    7) Methoxychlor

    C16H15Cl3O2

    72-43-5

    Methoxychlor.png

    345.6472

    346

    22.80

    8) 4-4'-DDT

    C14H9Cl5

    50-29-3

    4-4'-DDT.png

    354.4848

    260

    *

    19.48

    9) Aldrin

    C12H8Cl6

    34487-55-3

    Aldrin.png

    364.913

    145

    11.84

    10) Heptachlor

    C10H5Cl7

    76-44-8

    Heptachlor.png

    373.3156

    135-145

    *

    10.66

    11) Endrin Aldehyde

    C12H8Cl6O

    7421-93-4

    Endrin Aldehyde.png

    380.9075

    19.72

    12) Dieldrin

    C12H8Cl6O

    60-57-1

    Dieldrin.png

    380.9075

    330

    16.41

    13) Endrin

    C12H8Cl6O

    72-20-8

    Endrin.png

    380.9075

    **

    17.80

    14) Heptachlor epoxide

    C10H5Cl7O

    1024-57-3

    Heptachlor epoxide.png

    389.319

    135-145

    13.97

    15) Endosulfan I

    C9H6Cl6O3S

    19595-59-6

    Endosulfan I.png

    406.924

    15.25

    16) Endosulfan II

    C9H6Cl6O3S

    33213-65-9

    Endosulfan II.png

    406.924

    450

    18.45

    17) Endosulfan sulfate

    C9H6Cl6O4S

    1031-07-8

    Endosulfan sulfate.png

    422.924

    481

    20.21

    Q3. Using the data in Table 2, create a graph of the boiling points as a function of molecular weight. Is the trend in this graph the same as you observed for the series of n-alkanes? If not, what do you think makes it different?

    Q4. Examine the molecular structures of the compounds in Table 2. These compounds can be divided into three general types. Which ones would you group together into the three different types? Within a compound group, is there a relationship between structure, molecular weight and boiling point? Do you think that the compounds in Table 2 can be separated based on their boiling points alone?

    Role of the Stationary Phase

    Table 3. Common Polysiloxane Stationary Phases for GC Separations. http://delloyd.50megs.com/moreinfo/gcphases.html

    BONDED PHASE

    TEMP °C

    GENERAL USE OF PHASE

    EQUIVALENTS

    Methyl polysiloxane

    50-325

    Most frequently used phase in GC. Low selectivity, separates compounds according to boiling points. Excellent thermal stability

    SE-30, OV-1, OV-101, DB-1, SPB-1, BP-1, HP-1, ULTRA-1, RTx-1, AT-1, CPSil-5

    Methyl 5% Phenyl Polysiloxane

    50-325

    Similar to methyl polysiloxane but slightly more selective due to phenyl content. Excellent thermal stability.

    SE-54, OV-23, DB-5, SPB-5, BP-5, HP-5, ULTRA 2, RTx-5, CPSil-8

    Methyl 50% Phenyl Polysiloxane

    40-325

    Added selectivity due to higher phenyl content. Usually retains similar compounds longer than methyl silicone. Provides efficient separations of PAHS and biomedical samples such as drugs, sugars and steroids. Good thermal stability.

    OV-17, DB-17, SPB-7, BP-10, HP-17, RTx-17, AT-50,

    50% Trifluoropropyl 50% Methyl polysiloxane

    40-300

    Selectivity for compounds with lone pair electrons or carbonyl groups. Retains oxygenated compounds in the order ether, hydroxy, ester and keto Widely used as a confirmatory phase for chlorinated pesticides. Also suitable for PCB’s, phenols and nitroaromatics. Good thermal stability.

    DB-210, RTx-200, HP-210

    6% Cyanopropylphenyl 94% Methylpolysiloxane

    30-320

    An additional choice for a general purpose phase with nominal selectivity for polarizable and polar compounds. More of a boiling point phase than 007-1701; and exhibits less retention of polyaromatic compounds than 007-17. Good thermal stability.

    DB-1301, RTx-1301, HP-1301

    Methyl 7% Cyanopropyl 7% Phenyl Polysiloxane

    280

    Unique selectivity of cyanopropyl and phenyl groups provide efficient separations of derivitized sugars and many environmental samples. Not truly a polar phase. Good thermal stability

    DB-1701, CPSil-19, RTx-1701, AT-1701

    Methyl 25% Cyanopropyl 25% Phenyl Polysiloxane

    40-240

    Polar phase which provides efficient separations of polar molecules such as fatty acids and alditol acetate derivatives of sugars. Fair thermal stability

    DB-255, HP-255, CPSil-43, RTx-225, AT-255

    As you may have guessed from the exercises above, it is difficult to design a separation of organochlorine pesticides that depends on physical properties of the compounds alone. To alter the mobilities of the compounds to achieve an adequate separation we need to also consider their interactions with the stationary phase.

    Q5. Use the information in Table 3 above to find the column recommended for a boiling point-based separation of linear alkanes. What is the chemical composition of the columns suggested for the separation of alkanes?

    In Section 6.9 of EPA method 525.2 a bonded stationary phase is suggested.

    “6.9 Fused Silica Capillary Gas Chromatography Column -- Any capillary column that provides adequate resolution, capacity, accuracy, and precision (Section 10.0) can be used. Medium polar, low bleed columns are recommended for use with this method to provide adequate chromatography and minimize column bleed. A 30 m X 0.25 mm id fused silica capillary column coated with a 0.25 µm bonded film of polyphenylmethylsilicone (J&W DB-5.MS) was used to develop this method. Any column which provides analyte separations equivalent to or better than this column may be used.”

    Q6. From Table 3 and Figure 2 what are the compositions of the DB-5 and DB-1 stationary phases? Why is the DB-5 phase a better choice for separation of the organochlorine compounds listed in Table 2?

    Fig2.PNG

    Figure 2. Chemical structures of common GC stationary phases.

    The EPA method 525.2 states that any column that provides analytical separations equivalent or better than this one may be used.

    Q7. Of the column types listed in Table 3 what might you suggest as alternatives? What figures of merit would you use to determine whether a column provides a “better” separation?

    The actual column recommended by the EPA is not DB-5 but DB-5.MS. The MS column designation refers to a bonded siloxane phase with a slightly different chemical composition as shown in Figure 2, which improves the stability and can allow for higher maximum operating temperatures. This reduces column bleed, which is the loss of components of the stationary phase, especially problematic at higher temperatures. Column bleed can produce a high background, reducing the sensitivity of the MS measurements.

    Q8. What is column bleed? From the structures in Figure 2, why do you think that the DB-5.MS columns have reduced column bleed than those using the standard DB-5 stationary phase?

    Consider the chromatogram of a standard mixture of 20 pesticides shown below.

    Fig3.PNG

    Figure 3. Separation of a 20 pesticide mixture using chrysene-d12 as the internal standard. The separation was performed as described in EPA Method 525.2 except that the carrier gas was at 25 cm/s.

    Q9. The chromatogram in Figure 3 shows a separation of a standard containing 20 organochlorine pesticides plus an internal standard. How would you determine which peak correlates to each organochlorine compound? Be specific.

    Temperature Programming and Column Stability

    The chromatogram in Figure 3 was acquired by increasing the temperature as the separation progresses according to a set program. This is called temperature programming and is a common feature of gas chromatography. The effect of temperature programming on separation time and peak width is illustrated in the animation at http://www.shsu.edu/~chm_tgc/sounds/flashfiles/GCtemp.swf.

    Q10. Why is temperature programming commonly used with gas chromatography?

    Q11. Look at the maximum temperatures at which the stationary phases in Table 3 are stable. What is the maximum operating temperature for the DB-5 column?

    Evaluating the Performance of the Column for Quality Control

    Now that we have a column (stationary phase) and a temperature program to achieve separation how do we

    • Ensure that we do not overload the column?
    • Describe the quality of the separation?
    • Establish confidence in the quality of the signal intensity?

    Q12. What would an ideal chromatographic peak look like? What would a chromatographic peak look like if you overloaded the column? Why is it undesirable to overload a column?

    The following discussion regarding injection is from EPA method 525.2.

    “6.10.1 The GC must be capable of temperature programming and be equipped for splitless/split injection. On-column capillary injection is acceptable if all the quality control specifications in Section 9.0 and Section 10.0 are met. The injection tube liner should be quartz and about 3 mm in diameter. The injection system must not allow the analytes to contact hot stainless steel or other metal surfaces that promote decomposition.”

    10.2.3 Inject a 1 µL aliquot of a medium concentration calibration solution, for example 0.5-2 µg/L…”

    The instructions in section 10.2.3 indicate that a typical injection should be 1 µL. This injection size coupled with the EPA designated column size sets a limit on the maximum amount of material that can be placed onto the column. The capacity of the column, i.e. the maximum amount of analyte that should be injected, depends upon the volume of the stationary phase and the interaction between the stationary phase and the solute.

    Table 4. Column Capacity in ng http://www.chem.agilent.com/cag/cabu/colselect.htm

    Film Thickness (um)

    Column Diameter (mm)

    0.18-0.20

    0.25

    0.32

    0.53

    0.10

    20-35

    25-50

    35-75

    50-100

    0.25

    35-75

    50-100

    75-125

    100-250

    0.50

    75-150

    100-200

    125-250

    250-500

    1.00

    150-250

    200-300

    250-500

    500-1000

    3.00

    400-600

    500-800

    1000-2000

    5.00

    1000-1500

    1200-2000

    2000-3000


    Because the EPA method dictates the column used (or similar column) it also dictates the total amount of analyte that can be loaded onto the column.

    “6.9 Fused Silica Capillary Gas Chromatography Column -- Any capillary column that provides adequate resolution, capacity, accuracy, and precision (Section 10.0) can be used. Medium polar, low bleed columns are recommended for use with this method to provide adequate chromatography and minimize column bleed. A 30 m X 0.25 mm id fused silica capillary column coated with a 0.25 µm bonded film of polyphenylmethylsilicone (J&W DB-5.MS) was used to develop this method. Any column which provides analyte separations equivalent to or better than this column may be used.”

    If the capacity of the column is exceeded the shape of the chromatographic peak is altered from its “normal” Gaussian shape to an asymmetric shape. The figure below shows an example of an asymmetric peak shape that results from fronting. Peak tailing is also possible when columns are overloaded. An older EPA method required documentation that the chromatographic peaks are normal in shape.

    asymmetric peak shape.png

    If the column is overloaded one solution to the problem is to perform a “split” injection. In splitting, a portion of the sample is swept away in the carrier gas leaving only a fraction behind for injection. Split injections can be used to lower the amount injected to as low as 1% of the amount in the sample. This animation shows how a split injection is performed. http://www.instrumentalchemistry.com/gasphase/pages/split.htm

    Q13. A 1 L water sample containing 0.1 µg/L of DDT was concentrated to ~1 mL by the sample preparation procedure and 1 µL injected splitless onto a 30 m X 0.25 mm id fused silica capillary column coated with a 0.25 µm bonded film of DB-5.MS. Calculate the ng of material injected. Is this value greater or less than the capacity of the column?

    Our method must demonstrate its quality with respect to the baseline. In GC, bleeding of the stationary phase can occur, especially at higher temperatures. Bleeding affects the baseline noise in the spectra. Baseline noise affects the ability to quantitate a given chromatographic peak. This figure shows an example taken from an instrument manufacturer which illustrates the impact of baseline noise in a chromatogram.

    baseline noise.png

    Source http://www.waters.com/webassets/cms/category/media/detail_page_images/GCT_Premier_detail_2.jpg

    The upper chromatogram has a large baseline signal that registers at about 50% of the intensity of the peak at 15.70 min. The signal to noise (S/N) is calculated as:

    \[\dfrac{S}{N} = \dfrac{X_p - X_b}{pp_{baseline}} \nonumber\]

    where the signal (S) is defined by the difference in the integrals of Xp (the analyte peak at 15.70 min) and Xb is the integral of a similar area of the baseline. The noise in this formula is calculated as the peak-to-peak noise (ppbaseline) measured in a baseline region containing no peaks. In the top spectrum, the difference between the 15.70 peak intensity (100%) and the baseline intensity (~50%) divided by the peak-to-peak fluctuation in the baseline (shown as a redline) is only 4.91, whereas in the bottom spectrum with less background, a S/N of 39.50. It should be clear that reduction of the baseline bleed (and other contributors to background signals) will greatly enhance the S/N.

    Another quality check for the GC data specified by the EPA method is chromatographic resolution.

    “10.2.4.1 GC Performance -- Anthracene and phenanthrene should be separated by baseline. Benz[a]anthracene and chrysene should be separated by a valley whose height is less than 25% of the average peak height of these two compounds. If the valley between benz[a]anthracene and chrysene exceeds 25%, the GC column requires maintenance.”

    Q14. Evaluate the GC data below for benz[a]anthracene and chrysene, and determine if the GC column requires maintenance.

    GC data.png


    This page titled Gas Chromatography of Organochlorine Compounds is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Contributor.

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