Pyrene

Administrative data

Endpoint:

adsorption / desorption

Remarks:

adsorption

Type of information:

migrated information: read-across from supporting substance (structural analogue or surrogate)

Adequacy of study:

key study

Reliability:

2 (reliable with restrictions)

Rationale for reliability incl. deficiencies:

other: Secondary source, peer-reviewed data, acceptable for assessment

Data source

Referenceopen allclose all

Materials and methods

Principles of method if other than guideline:

Atmospheric monitoring of PAH: distribution in gas and particle phase

GLP compliance:

no

Type of method:

other: atmospheric monitoring

Media:

other: particle and gasphase

Test material

Specific details on test material used for the study:

Details on properties of test surrogate or analogue material (migrated information):
no data

Radiolabelling:

no

Study design

Test temperature:

ambient temperature

HPLC method

Details on study design: HPLC method:

not applicable

Batch equilibrium or other method

Analytical monitoring:

yes

Details on sampling:

no data

Details on matrix:

air particles

Details on test conditions:

no data

Computational methods:

not applicable

Results and discussion

Results: HPLC method

Details on results (HPLC method):

not applicable

Results: Batch equilibrium or other method

Adsorption and desorption constants:

no constants given (see below)

Recovery of test material:

not applicable

Concentration of test substance at end of adsorption equilibration period:

not applicable

Concentration of test substance at end of desorption equilibration period:

not applicable

Transformation products:

not measured

Details on results (Batch equilibrium method):

not applicable

Statistics:

not applicable

Any other information on results incl. tables

Excerpt from

ANNEX XV TRANSITIONAL DOSSIER - CTPHT CAS 65996-93-2, SECTION B. INFORMATION ON HAZARD AND RISK, B.4.1.1 Atmospheric degradation (or fate in the atmosphere)

. . . In the atmosphere PAHs are partitioned between the gas and particle phases, with the gas-particle partitioning depending on a number of factors, including the liquid-phase (or sub-cooled liquid-phase) vapour pressure of the PAH at the ambient atmospheric temperature, the surface area of the particles per unit volume of air, and the nature of the particle (Wania & Mackay, 1996; Pankow, 1987; Bidleman, 1988). As a first approximation, chemical compounds with liquid-phase vapour pressure of P_L< 10^-5 Pa at the ambient atmospheric temperature are present in the particle phase, and those with values of P_L> 10^-2 Pa at the ambient atmospheric temperature are essentially totally in the gas phase (Arey & Atkinson, 2003). As shown in measurements performed in Norway (Oslo), Germany (Bayreuth) and California USA (Torrance), the 2-4 ring PAHs with vapour pressures ≥ 10^-4 Pa are largely gas-phase species, whereas PAHs with 4 rings or more, with vapour pressure < 10^-4 Pa are particle-associated (see Table B.4.1).

TableB.4.1.    Summary of gas-particle phase partitioning

(PAH in bold = selected components of coal-tar pitch)

PAH (number of rings)	Vapour pressure (Pa)a)	Observed % in particulate phase
Naphthalene (2)	1.1·101	0b)			0e)
Acenaphthylene (3)	1.3·10-1
Acenaphthene (3)	4.0·10-1
Fluorene (3)	1.1·10-1	0b)
Anthracene (3)	8.7·10-4	3b)			0.5e)
Phenanthrene (3)	2.0·10-2	3b)	12.4c)	1.9d)	0.4e)
Fluoranthene (4)	6.0·10-3	54b)	49.7c)	19.1d)	5.9e)
Pyrene (4)	4.4·10-4	57b)	61.4c)	29.6d)	7.5e)
Benz(a)anthracene (4)	2.1·10-6	97b)	89.4c)	62.7d)
Chrysene (4)	1.4·10-6	99b)
Benzo(b)fluoranthene(5)	1.0·10-6	100b)	92.2c)	92.3d)
Benzo(a)pyrene (5)	5.3·10-8	100b)	100c)	100d)	98.3e)
Perylene (5)	1.8·10-8	100b)			90.0e)
Dibenzo[a,c]anthracene (5)	5.7·10-9	100b)
Dibenzo(a,h)anthracene (5)	4.9·10-9	100b)	100c)	100d)
Benzo(ghi)perylene (6)	1.0·10-8	100b)	100c)	100d)

Summary as given in EC (2001b).^a)Vapour pressures taken from Neiderfellner et al.(1997) and Oja & Suuberg (1998);

^b)Measurements made in Oslo, January/February 1979 (Thrane & Mikalsen, 1981);

^c)Annual mean measurements made in Bayreuth, Germany, May 1995-April 1996 (Horstmann & McLachlan, 1998);

^d)Summer mean measurements made in Bayreuth, Germany, May-October 1995 (Horstmann & McLachlan, 1998);

^e)Measurements made in Torrance, California, February 1986 (Arey et al., 1987).

References:

• Arey J, Zielinska B, Atkinson R, Winer AM (1987) Polycyclic aromatic hydrocarbon and nitroarene concentrations in ambient air during a winter-time high NOX episode in the Los Angeles basin. Atmosph Environ 21: 1437-1444.
• Bidleman, TF (1988) Atmospheric processes. Environ Sci Technol 22: 361-367.
• EC (2001b) Ambient Air Pollution by Polycyclic Aromatic Hydrocarbons (PAH). Position Paper. Prepared by the Working Group on Polycyclic Aromatic Hydrocarbons. July, 2001.
• Horstmann M, McLachlan MS (1998) Atmospheric deposition of semivolatile organic compounds to two forest canopies. Atmos Environ 32: 1799-1809.
• Neiderfellner J, Lenoir D, Matuschek G, Rehfeldt F, Utschick H, Bruggeman R (1997) Description of vapour pressures of polycyclic aromatic hydrocarbons by graph theoretical indices. Quant Struct-Act Relat 16: 38-48.
• Oja V, Suuberg EM (1998) Vapor pressures and enthalpies of sublimation of polycyclic aromatic hydrocarbons and their derivatives. J Chem Eng Data 43: 486-492.
• Pankow JF (1987) Review and comparative analysis of the theories on portioning between the gas and aerosol particulate phases in the atmosphere. Atmos Environ 21: 2275-2283.
• Thrane KE, Mikalsen A (1981) High-volume sampling of airborne polycyclic aromatic hydrocarbons using glass fibre filters and polyurethane foam. Atmos Environ 15: 909-918.
• Wania F, Mackay D (1996) Tracking the distribution of persistent organic pollutants. Environ Sci Technol 30: 390-396.

Applicant's summary and conclusion

Validity criteria fulfilled:

not applicable