ISOOCTYL ALCOHOL
Method number: |
PV2033 |
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Matrix: | Air |
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Target concentration: | 50 ppm (270 mg/m3) OSHA TWA PEL |
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Procedure: |
Samples are collected by drawing a known volume of air through a charcoal tube. Samples are
desorbed with 1 mL of 1:99 dimethyl formamide: carbon disulfide and analyzed by gas chromatography with a flame
ionization detector (GC-FID). |
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Air volume and sampling rate studied: | 10 liters at 0.2 liters per minute (Lpm) |
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Status of method: | Stopgap method. This method has been only partially evaluated and is presented for information and trial use. |
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Date: November, 1992 | Chemist: Bonny C. Decker |
Organic Service Branch I
OSHA Salt Lake Technical Center
Salt Lake City, Utah
1. General Discussion
1.1. Background
1.1.1. History of procedure
OSHA promulgated an exposure standard for isooctyl alcohol in January, 1989, at a level of 50 ppm. This study was undertaken to gather the
data necessary to verify the procedure we had been recommending. The procedure for collection
(charcoal tubes) and analysis (GC/FID) of isooctyl alcohol described in this evaluation is basically that used in OSHA method 07.(Ref. 5.1.) Isooctyl alcohol contains several peaks that elute over a time range of 1 minute. A solution
of 1 mL of 1:99 dimethyl formamide: carbon disulfide gives a constant desorption of 92.3% over the range of 0.25 mg to 2.49 mg. Isooctyl
alcohol had good retention and storage efficiencies on charcoal tubes.
1.1.2. Potential workplace exposure (Ref. 5.2.)
Isooctyl alcohol is used to form esters (such as
phthalates) for plasticizing vinyl and other resins.
1.1.3. Toxic Effects (This section is for information purposes and should not be taken as the basis for OSHA policy.)
Toxilogical data for isooctyl alcohol was unavailable. Documentation of Threshold Limit Values
and Biological Exposure Indices contained data for 2-ethyl-1-hexanol
(CAS# 104-76-7), not for isooctyl alcohol (CAS# 26952-21-6).(Ref. 5.3.)
2-Ethyl-1-hexanol is not a synonym for isooctyl alcohol. Isooctyl alcohol is a
mixture of 3-,4-, and 5-methyl heptanols.(Ref. 5.4.) The name was
chosen by the manufacturers as a simple, semidescriptive name for marketing purposes.(Ref. 5.2.)
1.1.4. Physical properties (Ref. 5.3.):
Compound: |
R-CH2OH |
| R= heptyl radicals |
Synonyms: |
Isooctanol |
Molecular weight: | 130.23 |
Density: | 0.834 |
Freezing point: | -76°C |
Boiling point: | 185°C |
Flash point: |
84°C (185°F) (open cup) |
Color: |
Colorless liquid |
Molecular formula: | C8H180 |
CAS: | 26952-21-6 |
IMIS: | A635 |
RTECS: | NS7700000;44590 |
DOT: | 8604 |
1.2. Limit defining parameters
1.2.1. The detection limit of the analytical procedure is 41.5 ug, with a 1 uL injection volume.
This is the smallest amount which could be detected under normal operating conditions.
1.2.2. The overall detection limit is 0.78 ppm. (All ppm values in this study are based on a 10 L air volume.)
1.3. Advantages
1.3.1. The sampling procedure is convenient.
1.3.2. The analytical method is reproducible and sensitive.
1.3.3. Reanalysis of samples is possible.
1.3.4. It may be possible to analyze other compounds at the same time.
1.3.5. Interferences may be avoided by proper selection of column and GC parameters.
2. Sampling procedure
2.1. Apparatus
2.1.1. A calibrated personal sampling pump, the flow of which can be determined within ± 5% at the recommended flow.
2.1.2. Charcoal tubes, lot 120, containing 100 mg
adsorbing section with a 50 mg backup section separated by a 2 mm portion of urethane foam, with a silanized glass wool plug before the adsorbing section and a 3 mm plug of urethane foam at the back of the backup section. The ends are flame sealed and the glass tube containing the adsorbent is 7 cm long, with a 6 mm O.D. and
4 mm I.D., SKC tubes or equivalent.
2.2. Sampling technique
2.2.1. The ends of the charcoal tube are opened immediately before sampling.
2.2.2. Connect the charcoal tube to the sampling pump with flexible tubing.
2.2.3. Tubes should be placed in a vertical position to minimize channeling, with the smaller section
towards the pump.
2.2.4. Air being sampled should not pass through any hose or tubing before entering the charcoal tube.
2.2.5. Seal the charcoal tube with plastic caps immediately after sampling. Seal each sample
lengthwise with OSHA Form-21 sealing tape.
2.2.6. With each batch of samples, submit at least one blank tube from the same lot used for samples. This tube should be subjected to exactly the same handling as the samples (break ends, seal, &
transport) except that no air is drawn through it.
2.2.7.
Transport the samples (and corresponding paperwork) to the lab for analysis.
2.2.8. bulks submitted for analysis must be shipped in a separate mailing container from other samples.
2.3. Desorption efficiency
Six tubes were liquid spiked at loadings of 0.25 mg (4.67 ppm), 0.83 mg (15.6 ppm), and 2.49 mg (46.7 ppm) isooctyl alcohol. They were allowed to equilibrate overnight at
room temperature. They were opened, each section placed into a separate 2 mL vial, desorbed with 1 mL of 1:99
dimethyl formamide: carbon disulfide for 30 minutes with occasional shaking, and analyzed by GC-FID. The overall average was 92.3% recovered.(Table 1) Values for the retention efficiency and the storage study were corrected for the desorption efficiency.
Table 1
Desorption Efficiency
|
Tube# | % Recovered | |
| 0.25 mg | 0.83 mg | 2.49 mg |
|
1 | 93.0 | 92.3 | 93.3 |
2 | 90.0 | 90.9 | 95.6 |
3 | 91.5 | 91.2 | 94.5 |
4 | 92.0 | 90.8 | 95.6 |
5 | 92.6 | 90.0 | 92.2 |
6 | 92.0 | lost | 92.5 |
average | 91.9 | 91.0 | 94.0 |
overall average | 92.3 |
standard deviation | ± 1.68 |
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2.4. Retention efficiency
Six tubes were liquid spiked with 2.49 mg (46.7 ppm) isooctyl alcohol, allowed to equilibrate overnight, and
then had 10 liters humid air (85% RH) pulled through them. They were opened, desorbed and analyzed by
GC-FID. The retention efficiency averaged 92.7%. There was no isooctyl alcohol found
on the backup portions of the tubes.(Table 2)
Table 2
Retention Efficiency
|
Tube # | % Recovered | % Recovered | Total |
| 'A' | 'B' | |
|
1 | 93.3 | 0.0 | 93.3 |
2 | 92.2 | 0.0 | 92.2 |
3 | 91.3 | 0.0 | 91.3 |
4 | 93.1 | 0.0 | 93.1 |
5 | 93.5 | 0.0 | 93.5 |
6 | 93.3 | 0.0 | 93.3 |
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| | average | 92.7 |
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2.5. Storage
Tubes were spiked with 2.49 mg (46.7 ppm) isooctyl alcohol and stored at room temperature until opened and analyzed. The recoveries averaged 102% for the 14 days stored.(Table 3)
Table 3
Storage Study
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|
Day | % Recovered |
|
8 | 103 |
8 | 104 |
8 | 104 |
14 | 100 |
14 | 101 |
14 | 100 |
|
average |
102 |
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2.6. Precision
The precision was calculated using the area counts from six injections of each standard at concentrations of
0.25, 0.83, 2.49 mg/mL isooctyl alcohol in 1:99 dimethyl
formamide: carbon disulfide. The pooled coefficient of variation was 0.0115.(Table 4)
Table 4
Precision Study
|
Injection |
Number | 0.25 mg/mL | 0.83 mg/mL | 2.49 mg/mL |
|
1 | 68295 | 211712 | 624546 |
2 | 69661 | 213739 | 632078 |
3 | 68623 | 214503 | 627399 |
4 | 70118 | 214381 | 620275 |
5 | 70579 | 214725 | 630681 |
6 | 69951 | 220254 | 622585 |
|
Average | 69538 | 214886 | 626261 |
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Standard |
Deviation | ± 893 | ± 2851 | ± 4625 |
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CV | 0.0128 | 0.0133 | 0.00738 |
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Pooled CV | 0.0115 |
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where:
A(1), A(2),A(3),A(4) = # of injections at each level
CVl, CV2, CV3, CV4 = Coefficients at each level
2.7. Air volume and sampling rate studied
2.7.1. The air volume studied is 10 liters.
2.7.2. The sampling rate studied is 0.2 liters per minute.
2.8. Interferences
Suspected interferences should be listed on sample data sheets.
2.9. Safety precautions
2.9.1. Sampling equipment should be placed on an employee in a manner that does not interfere with work performance or safety.
2.9.2. Safety glasses should be worn at all times.
2.9.3. Follow all safety practices that apply to the workplace being sampled.
3. Analytical method
3.1. Apparatus
3.1.1. Gas chromatograph equipped with a flame ionization detector. A HP 5890 II gas
chromatograph was used in this study.
3.1.2. GC column capable of separating the analyte and an internal standard from any interferences. The
column used in this study was a 60 meter DB-WAX capillary column 1.0µ d.f., and 0.32 mm
I.D.
3.1.3. An electronic integrator or some other suitable method of measuring peak areas.
3.1.4. Two milliliter vials with Teflon-lined caps.
3.1.5. A 10 µL syringe or other convenient size for sample injection.
3.1.6. Pipets for dispensing the desorbing solution. The Glenco 1 mL dispenser was used in this method.
3.1.7. Volumetric flasks - 5 mL and other convenient
sizes for preparing standards.
3.2 Reagents
3.2.1. Purified GC grade nitrogen, hydrogen, and air.
3.2.2. Isooctyl alcohol, Reagent grade
3.2.3. Carbon disulfide, Reagent grade
3.2.4. Dimethyl formamide, HPLC grade
3.2.5. p-Cymene, Reagent grade
3.2.6. The desorbing solution is 0.25 µL/mL p-cymene in 1:99 dimethyl formamide:carbon disulfide.
3.3. Sample preparation
3.3.1. Sample tubes are opened and the front and back section of each tube are placed in separate 2 mL vials.
3.3.2. Each section is desorbed with 1 mL of desorbing solution.
3.3.3. The vials are sealed immediately and allowed to desorb for 30 minutes with occasional shaking.
3.4. Standard preparation
3.4.1. Standards are prepared by diluting a known quantity of isooctyl alcohol with the desorbing solution. Standards prepared at 1 µL/mL isooctyl
alcohol in the desorbing solution is equivalent to 0.830 mg/mL.
3.4.2. At least two separate standards should be made. These standards should be within ± 5%, and then are averaged.
3.4.3. A third analytical standard should be prepared at
a higher concentration to check for linearity of the calibration. For this study two standards at
1 µL/mL (0.830 mg/mL) and one standard at 4 µL/mL
(3.32 mg/mL) isooctyl alcohol were used.
3.5. Analysis
3.5.1. Gas chromatograph conditions.
Flow rates (mL/min) | | Temperature (deg.C) |
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Nitrogen(make-up) | : 32 | Injector | : 180 |
Hydrogen(carrier) | : 2 | Detector | : 240 |
Hydrogen(detector) | : 60 | Column | : 65 |
Air | : 410 |
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Injection size | : 1 µL |
Elution time | : Range of 10.8 to 11.9 min. |
Chromatogram | : see Figure 1 |
3.5.2. Peak areas are measured by an integrator or other suitable means. The peak areas were summed.
3.6. Interferences (analytical)
3.6.1. Any compound having the general retention time of the analyte or the internal standard used is an interference. Possible interferences should be
listed on the sample data sheet. GC parameters should be adjusted if necessary so these interferences will pose no problems.
3.6.2. Retention time data on a single column is not considered proof of chemical identity. Samples over the target concentration should be confirmed by GC/Mass Spec or other suitable means.
3.7. Calculations
3.7.1. A curve with area counts versus concentration is calculated from the calibration standards.
3.7.2. The area counts for the samples are plotted with the calibration curve to obtain the concentration of isooctyl alcohol in solution.
3.7.3. To calculate the concentration of analyte in the air sample the following formulas are used:
(µg/m) (desorption volume) (desorption efficiency) |
= mass of analyte in sample |
(mass of analyte in sample) molecular weight |
= number of moles of analyte |
(number of moles of analyte) |
(molar volume at 25°C & 760mm) |
= |
volume the analyte will occupy at 25°C & 760mm |
(volume analyte occupies) (106)* (air volume) |
= ppm |
* All units must cancel.
3.7.4. The above equations can be consolidated to form the following formula. To calculate the ppm of
analyte in the sample based on a 10 liter air sample:
(µg/mL)(DV)(24.45)(106) (10 L)(DE)(MW) |
× |
(g) (1000 mg) |
× |
(mg) (1000 µg) |
= ppm |
µg/mL | = | concentration of analyte in sample or standard |
24.45 | = | Molar volume (liters/mole) at 25° and 760 mm Hg. |
MW | = | Molecular weight (g/mole) |
DV | = | Desorption volume |
10 L | = | 10 liter air sample |
DE | = | Desorption efficiency |
3.7.5. This calculation is done for each section of the sampling tube and the results added together.
3.8. Safety precautions
3.8.1. All handling of solvents should be done in a hood.
3.8.2. Avoid skin contact with all chemicals.
3.8.3. Wear safety glasses, gloves and a lab coat at all times.
4. Recommendations for further study
Collection studies should be performed.
Figure 1. An analytical standard of 0.25 mg/mL isooctyl alcohol in 1:99 dimethyl formamide:carbon disulfide with 0.25 µL/mL
p-cymene internal standard. A chart speed of 1.0 cm/min was used.
5. References
5.1. Shulsky, M., Method 07, "Organic Vapors", Organic Methods Evaluation Branch, OSHA Analytical Laboratory, 1989.
5.2. "Kirk-Othmer Encyclopedia of Chemical Technology", Second
Edition, John Wiley & Sons, Inc., New York, 1967, Vol. 14, p. 373-375.
5.3. "Documentation of the Threshold Limit Values and Biological Exposure Indices", Fifth Edition, American Conference of Governmental Industrial Hygienists, Inc., Cincinnati, 1986, p. 332.
5.4. Chem Service, Inc., Material Safety Data Sheet (MSDS) for
Isooctyl Alcohol, July 1991.
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