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Environ Sci Process Impacts

Title:		A critical assessment of the environmental fate of linear and cyclic volatile methylsiloxanes using multimedia fugacity models
Author(s):		Panagopoulos D; MacLeod M;
Address:		"Department of Environmental Science and Analytical Chemistry, ACES, Stockholm University, Svante Arrhenius vag 8, SE-114 18 Stockholm, Sweden. drdimitripanagopoulos@gmail.com and Environmental Energy Technologies Division, Lawrence Berkeley National Laboratory, LBNL, 1 Cyclotron Road, 94720 Berkeley, California, USA. Department of Environmental Science and Analytical Chemistry, ACES, Stockholm University, Svante Arrhenius vag 8, SE-114 18 Stockholm, Sweden. drdimitripanagopoulos@gmail.com"
Journal Title:		Environ Sci Process Impacts
Year:		2018
Volume:		20
Issue:		1
Page Number:		183 - 194
DOI:		10.1039/c7em00524e
ISSN/ISBN:		2050-7895 (Electronic) 2050-7887 (Linking)
Abstract:		"We apply multimedia models to systematically evaluate the fate profile of cyclic volatile methyl siloxanes (VMS) D(4), D(5) and D(6), and the linear VMS L(4) and L(5) using recently reported measurements of their partition ratios between organic carbon and water (K(OC)), their salting out constants (K(s)), and their enthalpy of sorption to organic carbon (DeltaH(OC)). Our assessment follows a multi-stage strategy where the environmental fate of the chemicals is explored in generic regional models with increasing fidelity to the real system and in a region-specific model. Modeled emissions of VMS to air remained in air and were degraded or advected out of the system with overall residence times ranging from 2.4 to 2.5 days, while emissions to water resulted in accumulation in sediment and longer residence times ranging from 29.5 to 1120 days. When emitted to water the modeled residence times of VMS in the sediment exceeded the REACH criterion for persistence in freshwater sediments. Reported K(OC) measurements for D(5) differ by 1 log unit, which results in a 500-day difference in the overall residence times calculated in the generic regional modeling. In the specific-region modeling assessment for Adventfjorden, Svalbard in Norway, the different K(OC) measurements of D(5) resulted in a 200-day difference in overall residence times. Model scenarios that examined combinations of previously published DeltaH(OC) or enthalpy of phase change between octanol and water (DeltaH(OW)) for D(5) in combination with the range of the K(OC) measurements resulted in 1100-days difference in overall residence times. Our results demonstrate that residence times of VMS in aquatic systems are highly sensitive to their degree of sorption to organic carbon, and that residence times of VMS likely exceed several persistence criteria and therefore they cannot be considered as non-persistent"
Keywords:		"Environmental Monitoring/*methods Estuaries Fresh Water/chemistry Geologic Sediments/chemistry *Models, Theoretical Multimedia Norway Risk Assessment Seawater/chemistry Siloxanes/*analysis/chemistry Structure-Activity Relationship Volatile Organic Compoun;"
Notes:		"MedlinePanagopoulos, Dimitri MacLeod, Matthew eng England 2018/01/05 Environ Sci Process Impacts. 2018 Jan 24; 20(1):183-194. doi: 10.1039/c7em00524e"