Volatile Organic Compounds (Screening) (2549)

​VOLATILE ORGANIC COMPOUNDS (SCREENING)

FORMULA

see Table 1

MW: see Table 1

METHOD: 2549, Issue 1

CAS: see Table 1

EVALUATION: PARTIAL

OSHA : NIOSH: varies with compound ACGIH:

PROPERTIES:

2549

RTECS: see Table 1

Issue 1: 15 May 1996

See Table 1

SYNONYMS: VOCs; See individual compounds in Table 1

SAMPLING SAMPLER:

THERMAL DESORPTION TUBE (multi-bed sorbent tubes containing graphitized carbons and carbon molecular sieve sorbents [See Appendix])

FLOW RATE:

0.01 to 0.05 L/min

VOL-MIN: -MAX:

1L 6L

SHIPMENT:

MEASUREMENT TECHNIQUE:

THERMAL DESORPTION, GAS CHROMATOGRAPHY, MASS SPECTROMETRY

ANALYTE:

See Table 1

DESORPTION:

Thermal desorption

INJECTION VOLUME:

Defined by desorption split flows (See Appendix)

Ambient in storage containers

SAMPLE STABILITY:

Compound dependent (store @ -10 C)

BLANKS:

1 to 3 per set

TEMPERATURE-DESORPTION: 300 C for 10 min. -DETECTOR (MS): 280 C -COLUMN: 35 C for 4 min; 8 C/min to 150 C, 15 C/min to 300 C CARRIER GAS:

Helium

COLUMN:

30 meter DB-1, 0.25-mm ID, 1.0-µm film, or equivalent

CALIBRATION:

Identification based on mass spectra interpretation and computerized library searches.

RANGE:

not applicable

ESTIMATED LOD:

100 ng per tube or less

PRECISION ( r):

not applicable

ACCURACY

RANGE STUDIED:

not applicable

BIAS:

not applicable

OVERALL PRECISION ( ACCURACY:

rT

):

not applicable not applicable

APPLICABILITY:This method has been used for the characterization of environments containing mixtures of volatile organic compounds (See Table 1). The sampling has been conducted using multi-bed thermal desorption tubes. The analysis procedure has been able to identify a wide range of organic compounds, based on operator expertise and library searching. INTERFERENCES:Compounds which coelute on the chromatographic column may present an interference in the identification of each compound. By appropriate use of background subtraction, the mass spectrometrist may be able to obtain more representative spectra of each compound and provide a tentative identity (See Table 1). OTHER METHODS: Other methods have been published for the determination of specific compounds in air by thermal desorption/gas chromatography [1-3]. One of the primary differences in these methods is the sorbents used in the thermal desorption tubes.

NIOSH Manual of Analytical Methods (NMAM), Fourth Edition, 5/15/96 ​VOLATILE ORGANIC COMPOUNDS (SCREENING): METHOD 2549, Issue 1, dated 15 May 1996 - Page 2 of 8

REAGENTS:

EQUIPMENT:

1. Air, dry 2. Helium, high purity 3. Organic compounds of interest for mass spectra verification (See Table 1).* 4. Solvents for preparing spiking solutions: carbon disulfide (low benzene chromatographic grade), methanol, etc.(99+% purity)

1. Sampler: Thermal sampling tube, ¼” s.s. tube, multi-bed sorbents capable of trapping organic compounds in the C3-C16 range. Exact sampler configuration depends on thermal desorber system used. See Figure 1 for example. 2. Personal sampling pump, 0.01 to 0.05 L/min, with flexible tubing. 3. Shipping containers for thermal desorber sampling tubes. 4. Instrumentation: thermal desorption system, focusing capability, desorption temperature appropriate to sorbents in tube (~300 C), and interfaced directly to a GC-MS system. 5. Gas chromatograph with injector fitted with 1/4" column adapter, 1/4" Swagelok nuts and Teflon ferrules (or equivalent). 6. Syringes: 1-µL, 10-µL (liquid); 100-µL, 500-µL (gas tight) 7. Volumetric Flasks, 10-mL. 8. Gas bulb, 2 L

• See SPECIAL PRECAUTIONS

SPECIAL PRECAUTIONS: Some solvents are flammable and should be handled with caution in a fume hood. Precautions should be taken to avoid inhalation of the vapors from solvents as well. Skin contact should be avoided. SAMPLING: NOTE:

1. 2.

3.

4.

5. 6.

Prior to field use, clean all thermal desorption tubes thoroughly by heating at or above the intended tube desorption temperature for 1-2 hours with carrier gas flowing at a rate of at least 50 mL/min. Always store tubes with long-term storage caps attached, or in containers that prevent contamination. Identify each tube uniquely with a permanent number on either the tube or tube container. Under no circumstances should tape or labels be applied directly to the thermal desorption tubes. Calibrate each personal sampling pump with a representative sampler in line. Remove the caps of the sampler immediately before sampling. Attach sampler to personal sampling pump with flexible tubing. NOTE: With a multi-bed sorbent tube, it is extremely important to sample in the correct direction, from least to maximum strength sorbent. For general screening, sample at 0.01 to 0.05 L/min for a maximum sample volume of 6 L. Replace caps immediately after sampling. Keep field blanks capped at all times. Tubes can act as diffusive samplers if left uncapped in a contaminated environment. Collect a "humidity test" sample to determine if the thermal adsorption tubes have a high water background. NOTE: At higher sample volumes, additional analyte and water (from humidity) may be collected on the sampling tube. At sufficiently high levels of analyte or water in the sample, the mass spectrometer may malfunction during analysis resulting in loss of data for a given sample. Collect a "control" sample. For indoor air samples this could be either an outside sample at the same location or an indoor sample taken in a non-complaint area. Ship in sample storage containers at ambient temperature. Store at -10 C.

SAMPLE PREPARATION: 7.

Allow samples to equilibrate to room temperature prior to analysis. Remove each sampler from its storage container.

NIOSH Manual of Analytical Methods (NMAM), Fourth Edition, 5/15/96 ​VOLATILE ORGANIC COMPOUNDS (SCREENING): METHOD 2549, Issue 1, dated 15 May 1996 - Page 3 of 8

8. 9.

Analyze "humidity test" sampler first to determine if humidity was high during sampling (step 10). If high humidity, dry purge the tubes with purified helium at 50 to 100 mL/min for a maximum of 3 L at ambient temperature prior to analysis. . 10. Place the sampler into the thermal desorber. Desorb in reverse direction to sampling flow.

CALIBRATION AND QUALITY CONTROL: 11. Tune the mass spectrometer according to manufacturer’s directions to calibrate. 12. Make at least one blank run prior to analyzing any field samples to ensure that the TD-GC-MS system produces a clean chromatographic background. Also make a blank run after analysis of heavily concentrated samples to prevent any carryover in the system. If carryover is observed, make additional blank runs until the contamination is flushed from the thermal desorber system. 13. Maintain a log of thermal desorber tube use to record the number of times used and compounds found. If unexpected analytes are found in samples, the log can be checked to verify if the tube may have been exposed to these analytes during a previous sampling use. 14. Run spiked samples along with the screening samples to confirm the compounds of interest. To prepare spiked samples, use the procedure outlined in the Appendix . MEASUREMENT: 15. See Appendix for conditions. MS scan range should cover the ions of interest, typically from 20 to 300 atomic mass units (amu). Mass spectra can either be identified by library searching or by manual interpretation (see Table 1). In all cases, library matches should also be checked for accurate identification and verified with standard spikes if necessary. EVALUATION OF METHOD: The method has been used for a number of field screening evaluations to detect volatile organic compounds. Estimate of the limit of detection for the method is based on the analysis of spiked samples for a number of different types of organic compounds. For the compounds studied, reliable mass spectra were collected at a level of 100 ng per compound or less. In situations where high levels of humidity may be present on the sample, some of the polar volatile compounds may not be efficiently collected on the internal trap of the thermal desorber. In these situations, purging of the samples with 3 L of helium at 100 mL/min removed the excess water and did not appreciably affect the recovery of the analytes on the sample. REFERENCES: [1] [2]

[3] [4]

Health and Safety Executive [1992]. MDHS 72 - Volatile organic compounds in air. Methods for the determination of hazardous substances. HMSO: London: ISBN 0-11-885692-8. McCaffrey CA, MacLachlan J, Brookes BI [1994]. Adsorbent tube evaluation for the preconcentration of volatile organic compounds in air for analysis by gas chromatography-mass spectrometry. Analyst 119:897-902. Bianchi AP, Varney MS [1992]. Sampling and analysis of volatile organic compounds in estuarine air by gas chromatography and mass spectrometry. J. Chromatogr. 643:11-23. EPA [1984]. Environmental Protection Agency Air Toxics Method T01. Rev. 1.0 (April, 1984): Method for the determination of volatile organic compounds in ambient air using Tenax(R) adsorption and gas chromatography/mass spectrometry (GC/MS), Section 13.

METHOD WRITTEN BY: Ardith A. Grote and Eugene R. Kennedy, Ph.D., NIOSH, DPSE

NIOSH Manual of Analytical Methods (NMAM), Fourth Edition, 5/15/96 ​VOLATILE ORGANIC COMPOUNDS (SCREENING): METHOD 2549, Issue 1, dated 15 May 1996 - Page 4 of 8

TABLE 1. COMMON VOLATILE ORGANIC COMPOUNDS WITH MASS SPECTRAL DATA Compound /Synonyms

CAS# RTECS

Empirical Formula

MWa

BPb ( C)

VPc @ 25 C mm Hg kPa

Characteristic Ions, m/z

80.1

95.2

78*

Aromatic Hydrocarbons Benzene /benzol

71-43-2 CY1400000

C6H6

78.11

Xylene /dimethyl benzene

1330-20-7 ZE2100000

C8H10

106.7

12.7

91, 106*, 105

o-xylene

144.4

6.7

0.9

m-xylene

139.1

8.4

1.1

p-xylene

138.4

8.8

1.2

Toluene /toluol

108-88-3 XS5250000

C7H8

92.14

110.6

28.4

3.8

91, 92*

Aliphatic Hydrocarbons n-Pentane

109-66-0 RZ9450000

C5H12

72.15

36.1

512.5

68.3

43, 72*, 57

n-Hexane /hexyl-hydride

110-54-3 MN9275000

C6H14

86.18

68.7

151.3

20.2

57, 43, 86*, 41

n-Heptane

142-82-5 MI7700000

C7H16

100.21

98.4

45.8

6.1

43, 71, 57, 100*,41

n-Octane

111-65-9 RG8400000

C8H18

114.23

125.7

14.0

1.9

43, 85, 114*, 57

n-Decane /decyl hydride

124-18-5 HD6500000

C10H22

142.29

174

1.4

0.2

43, 57, 71, 41, 142*

Acetone /2-propanone

67-64-1 AL3150000

C3H6O

58.08

56

266

35.5

43, 58*

2-Butanone /methyl ethyl ketone

78-93-3 EL6475000

C4H8O

72.11

79.6

100

13

43, 72*

Methyl isobutyl ketone /MIBK, hexone

108-10-1 SA9275000

C6H12O

100.16

117

15

2

43, 100*, 58

Cyclohexanone /cyclohexyl ketone

108-94-1 GW1050000

C6H10O

98.15

155

2

0.3

55, 42, 98*, 69

Methanol /methyl alcohol

67-56-1 PC1400000

CH3OH

32.04

64.5

115

15.3

31, 29, 32*

Ethanol /ethyl alcohol

64-17-5 KQ6300000

C2H5OH

46.07

78.5

42

5.6

31, 45, 46*

Isopropanol /1-methyl ethanol

67-63-0 NT8050000

C3H7OH

60.09

82.5

33

4.4

45, 59, 43

Butanol /butyl alcohol

71-36-3 EO1400000

C4H9OH

74.12

117

4.2

0.56

56, 31, 41, 43

Ketones

Alcohols

NIOSH Manual of Analytical Methods (NMAM), Fourth Edition, 5/15/96 ​VOLATILE ORGANIC COMPOUNDS (SCREENING): METHOD 2549, Issue 1, dated 15 May 1996 - Page 5 of 8 CAS# RTECS

Empirical Formula

MWa

BPb ( C)

VPc @ 25 C

Butyl cellosolve /2-butoxyethanol

111-76-2 KJ8575000

C6H14 O2

118.17

171

0.8

0.11

57, 41, 45, 75, 87

Diethylene glycol ethyl ether /Carbitol

111-90-0 KK8750000

C6H14O3

134.17

202

0.08

0.01

45, 59, 72, 73, 75, 104

Phenol /hydroxybenzene

108-95-2 SJ3325000

C6H5OH

94.11

182

47

0.35

94*, 65, 66, 39

Cresol

1319-77-3 GO5950000

C7H7OH

108.14

2-methylphenol

95-48-7

190.9

1.9

0.25

3-methylphenol

108-39-4

202.2

1.0

0.15

4-methylphenol

106-44-5

201.9

0.8

0.11

Compound /Synonyms

mm Hg kPa

Characteristic Ions, m/z

Glycol Ethers

Phenolics

108*, 107, 77, 79

Chlorinated Hydrocarbons Methylene chloride /dichloromethane

75-09-2 PA8050000

CH2Cl2

84.94

40

349

47

86*, 84, 49, 51

1,1,1-Trichloroethane /methyl chloroform

71-55-6 KJ2975000

CCl3CH3

133.42

75

100

13.5

97, 99, 117, 119

Perchloroethylene /hexachloroethane

127-18-4 KX3850000

CCl3CCl3

236.74

187 (subl)

0.2

<0.1

164*, 166, 168, 129, 131, 133, 94, 96

C6H4Cl2

147.0

o-,pDichlorobenzenes

146*, 148, 111, 113, 75

/1,2-dichlorobenzene

95-50-1 CZ4500000

172-9

1.2

0.2

/1,4dichlorobenzene

106-46-7 CZ4550000

173.7

1.7

0.2

1,1,2-Trichloro-1,2,2trifluoroethane /Freon 113

76-13-1 KJ4000000

CCl2FCClF2

187.38

47.6

384

38

d-Limonene

5989-27-5 OS8100000

C10H16

136.23

176

1.2

68, 67, 93, 121, 136*

Turpentine (Pinenes)

8006-64-2

C10H16

136.23

156 to 170

4@ 20

93, 121, 136*, 91

101, 103, 151, 153, 85, 87

Terpenes

-pinene

80-56-8

156

-pinene

127-91-3

165

Aldehydes Hexanal /caproaldehyde

66-25-1 MN7175000

C6H12O

100.16

131

10

NIOSH Manual of Analytical Methods (NMAM), Fourth Edition, 5/15/96

1.3

44, 56, 72, 82, 41 ​VOLATILE ORGANIC COMPOUNDS (SCREENING): METHOD 2549, Issue 1, dated 15 May 1996 - Page 6 of 8 Compound /Synonyms

CAS# RTECS

Empirical Formula

MWa

BPb ( C)

VPc @ 25 C

Benzaldehyde /benzoic aldehyde

100-52-7 CU4375000

C7H12O

106.12

179

1.0

0.1

77, 105, 106*, 51

Nonanal /pelargonic aldehyde

124-19-6 RA5700000

C9H18O

142.24

93

23

3

43, 44, 57, 98, 114

Ethyl acetate /acetic ether

141-78-6 AH5425000

C4H8O2

88.1

77

73

9.7

43, 88*, 61, 70, 73, 45

Butyl acetate /acetic acid butyl ester

123-86-4 AF7350000

C6H12O2

116.16

126

10

1.3

43, 56, 73, 61

Amyl acetate /banana oil

628-63-7 AJ1925000

C7H14O2

130.18

149

4

0.5

43, 70, 55, 61

556-67-2 GZ4397000

C8H24O4Si4

296.62

175

mm Hg kPa

Characteristic Ions, m/z

Acetates

Other Octamethylcyclotetrasiloxane

281, 282, 283

a

Molecular Weight Boiling Point c Vapor Pressure

• Indicates molecular ion

b

APPENDIX Multi-bed sorbent tubes: Other sorbent combinations and instrumentation/conditions shown to be equivalent may be substituted for those listed below. In particular, if the compounds of interest are known, specific sorbents and conditions can be chosen that work best for that particular compound(s). The tubes that have been used in NIOSH studies with the Perkin Elmer ATD system are ¼” stainless steel tubes, and are shown in the diagram below:

NIOSH Manual of Analytical Methods (NMAM), Fourth Edition, 5/15/96 ​VOLATILE ORGANIC COMPOUNDS (SCREENING): METHOD 2549, Issue 1, dated 15 May 1996 - Page 7 of 8

Figure 1 Carbopack™ and Carboxen™ adsorbents are available from Supelco, Inc.

Preparation of spiked samples: Spiked tubes can be prepared from either liquid or gas bulb standards. Liquid standards: Prepare stock solutions by adding known amounts of analytes to 10-mL volumetric flasks containing high purity solvent (carbon disulfide, methanol, toluene). Solvents are chosen based on solubility for the analytes of interest and ability to be separated from the analytes when chromatographed. Highly volatile compounds should be dissolved in a less volatile solvent. For most compounds, carbon disulfide is a good general purpose solvent, although this will interfere with early eluting compounds. Gas bulb standards: Inject known amounts of organic analytes of interest into a gas bulb of known volume filled with clean air [4]. Prior to closing the bulb, place a magnetic stirrer and several glass beads are placed in the bulb to assist in agitation after introduction of the analytes. After injection of all of the analytes of interest into the bulb, warm the bulb to 50 C and place it on a magnetic stirring plate and stir for several minutes to ensure complete vaporization of the analytes. After the bulb has been stirred and cooled to room temperature, remove aliquots from the bulb with a gas syringe and inject into a sample tube as described below. Tube spiking: Fit a GC injector with a ¼" column adapter. Maintain the injector at 120 C to assist in vaporization of the injected sample. Attach cleaned thermal desorption tubes to injector with ¼” Swagelok nuts and Teflon ferrules, and adjust helium flow though the injector to 50 mL/min. Attach the sampling tube so that flow direction is the same as for sampling. Take an aliquot of standard solution (gas standards 100 to 500 µL; liquid standards, 0.1 to 2 µL) and inject into the GC injector. Allow to equilibrate for 10 minutes. Remove tube and analyze by thermal desorption using the same conditions as for field samples. Instrumentation:Actual media, instrumentation, and conditions used for general screening of unknown environments are as follows: Perkin-Elmer ATD 400 (automated thermal desorption system) interfaced directly to a Hewlett-Packard 5980 gas chromatograph/HP5970 mass selective detector and data system.

NIOSH Manual of Analytical Methods (NMAM), Fourth Edition, 5/15/96 ​VOLATILE ORGANIC COMPOUNDS (SCREENING): METHOD 2549, Issue 1, dated 15 May 1996 - Page 8 of 8

ATD conditions: Tube desorption temperature: 300 C Tube desorption time: 10 min. Valve/transfer line temperatures: 150 C Focusing trap: Carbopack B/Carboxen 1000, 60/80 mesh, held at 27 C during tube desorption Focusing trap desorption temperature: 300 C Desorption flow: 50-60 mL/min. Inlet split: off Outlet split: 20 mL/min. Helium: 10 PSI GC conditions: DB-1 fused silica capillary column, 30 meter, 1-µm film thickness, 0.25-mm I.D. Temperature program: Initial 35 C for 4 minutes, ramp to 100 C at 8 /min., then ramp to 300 C at 15 /min, hold 1-5 minutes. Run time: 27 min. MSD conditions: Transfer line: 280 C Scan 20-300 amus, EI mode EMV: set at tuning value Solvent delay: 0 min. for field samples; if a solvent-spiked tube is analyzed, a solvent delay may be necessary to prevent MS shutdown caused by excessive pressure.

NIOSH Manual of Analytical Methods (NMAM), Fourth Edition, 5/15/96