Modeling the transport of organic chemicals between polyethylene passive samplers and water in finite and infinite bath conditions

There is a growing interest in assessing the concentration and distribution of new nonregulated organic compounds (emerging contaminants) in the environment. The measurement of freely dissolved concentrations using conventional approaches is challenging because of the low concentrations that may be encountered and their temporally variable emissions. Absorption-based passive sampling enables the estimation of freely dissolved concentrations of hydrophobic contaminants of emerging concern in water. In the present study, calibration was undertaken for 2 polymers, low-density polyethylene (LDPE) and silicone rubber for 11 fragrances, 5 endocrine-disrupting compounds, 7 ultraviolet (UV) filters, and 8 organophosphate flame retardant compounds. Batch experiments were performed to estimate contaminant diffusion coefficients in the polymers (Dp ), which in general decreased with increasing molecular weight. The values for fragrances, endocrine-disrupting compounds, and UV filters were in ranges similar to those previously reported for polycyclic aromatic hydrocarbons, but were 1 order of magnitude lower for organophosphate flame retardant compounds. Silicone rubber had higher Dp values than LDPE and was therefore selected for further experiments to calculate polymer/water partition coefficients (KPW ). The authors observed a positive correlation between log KPW and log octanol/water partition coefficient values. Field testing of silicone rubber passive samplers was undertaken though exposure in the River Alna (Norway) for an exposure time of 21 d to estimate freely dissolved concentration. Some fragrances and UV filters were predominant over other emerging and regulated contaminants, at levels up to 1600 ng L(-1) for galaxolide and 448 ng L(-1) for octocrylene. Environ Toxicol Chem 2016;35:2162-2172. © 2016 SETAC.

Section: Methodsmentioning

confidence: 99%

Section: Theorymentioning

confidence: 99%

Determination of silicone rubber and low‐density polyethylene diffusion and polymer/water partition coefficients for emerging contaminants

Pintado-Herrera

Lara-Martín

González-Mazo

et al. 2016

“…Each transport mechanism contributes to the resistance to mass transfer (1/k o ), calculated using Equation 1, with k w and k s as the mass transfer coefficients in the water and the silicone rubber polymer respectively, and K sw the silicone/water partition coefficient [26,29,30]. We focused only on the theory for membrane-free or monophasic samplers, such as silicone rubber plates.…”

Section: Mass Transfer Resistance Model In Silicone Rubber-based Passmentioning

confidence: 99%

“…It is a simple and approximated model, unlike the 2-phase Fickian model [29] (considering a time-dependent D s and resulting in nonlinear diffusion profiles in the polymer) that would lead to more accurate results. It is a simple and approximated model, unlike the 2-phase Fickian model [29] (considering a time-dependent D s and resulting in nonlinear diffusion profiles in the polymer) that would lead to more accurate results.…”

Section: Mass Transfer Resistance Model In Silicone Rubber-based Passmentioning

confidence: 99%

“…Transport across the biofilm layer for long exposure in water was neglected in the present work. Each transport mechanism contributes to the resistance to mass transfer (1/k o ), calculated using Equation 1, with k w and k s as the mass transfer coefficients in the water and the silicone rubber polymer respectively, and K sw the silicone/water partition coefficient [26,29,30].…”

Section: Mass Transfer Resistance Model In Silicone Rubber-based Passmentioning

confidence: 99%

See 1 more Smart Citation

Calibration of silicone rubber rods as passive samplers for pesticides at two different flow velocities: Modeling of sampling rates under water boundary layer and polymer control

Martín¹,

Margoum²,

Jolivet³

et al. 2018

There is a need to determine time-weighted average concentrations of polar contaminants such as pesticides by passive sampling in environmental waters. Calibration data for silicone rubber-based passive samplers are lacking for this class of compounds. The calibration data, sampling rate (R ), and partition coefficient between silicone rubber and water (K ) were precisely determined for 23 pesticides and 13 candidate performance reference compounds (PRCs) in a laboratory calibration system over 14 d for 2 water flow velocities, 5 and 20 cm s . The results showed that an in situ exposure duration of 7 d left a silicone rubber rod passive sampler configuration in the linear or curvilinear uptake period for 19 of the pesticides studied. A change in the transport mechanism from polymer control to water boundary layer control was observed for pesticides with a log K of approximately 3.3. The PRC candidates were not fully relevant to correct the impact of water flow velocity on R . We therefore propose an alternative method based on an overall resistance to mass transfer model to adjust R from laboratory experiments to in situ hydrodynamic conditions. We estimated diffusion coefficients (D ) and thickness of water boundary layer (δ ) as adjustable model parameters. Log D values ranged from -12.13 to -10.07 m s . The estimated δ value showed a power function correlation with water flow velocity. Environ Toxicol Chem 2018;37:1208-1218. © 2017 SETAC.

A method to account for the effect of hydrodynamics on polar organic compound uptake by passive samplers

Booij

Maarsen

Theeuwen

et al. 2017

9Mass transfer coefficients of the water boundary layer (kw) were measured using alabaster dissolution 10 kinetics in a diffusion cell that was operated at stirring rates between 90 and 600 min -1 , aiming to 11 provide a more robust characterisation of the effect of hydrodynamics on the uptake of polar 12 compounds by passive samplers, as compared with characterisations in terms of stirring rates and water 13 flow velocities. The measured kw helped to quantitatively understand calcium sulphate transport through 14 a poly(ethersulfone) membrane and two water boundary layers (at both sides of the membrane). 15Alabaster based kw were used to understand atrazine transport in the diffusion cell, allowing the 16 conclusion that atrazine transport in the membrane is via the pore space, rather than via the polymer 17 matrix. The merits of measuring alabaster dissolution rates for passive sampler calibration and 18 application in the field is discussed. We propose that passive sampler calibrations be carried out under