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A New Film-based Passive Sampler for Moderately Hydrophobic Organic Compounds Wenjian Lao, You-wei Hong, David Tsukada, Keith A. Maruya, and Jay J. Gan Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.6b04750 • Publication Date (Web): 23 Nov 2016 Downloaded from http://pubs.acs.org on November 27, 2016
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Table of Contents (TOC) Art
7000
Concentrations in PMMAfilms (ng/g)
B
Fipronil desulfinyl Fipronil sulfide Fipronil Fipronil sulfone
6000 5000 4000 3000 2000 1000
O
0 Control
MeOH
MeOH/EE
IPA
EE
O 4.8
1.2e+7 1.0e+7
Fipronil desulfinyl Fipronil sulfide Fipronil Fipronil sulfone Regression line
n PMMA
8.0e+6 6.0e+6
4.6
Measured log Kpw
4.4
Regression line +/- Standard error
4.2
Log Kpw
Concentrations on PMMA films (ng/L)
1.4e+7
4.0 3.8 3.6
4.0e+6
3.4 2.0e+6
3.2 0.0
3.0 0
10
20
30
Time (h)
40
50
60
2.8 2
3
4
5
6
Log Kow
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A New Film-based Passive Sampler for Moderately Hydrophobic Organic Compounds
2
Wenjian Lao†, Youwei Hong†‡§, David Tsukada†, Keith A. Maruya† and Jay Gan‡*
3 4 †
5 6
‡
7
§
Southern California Coast Water Research Project Authority, Costa Mesa, 92626, CA
Department of Environmental Sciences, University of California, Riverside, 92521, CA
Institute of Urban Environment, Chinese Academy of Sciences, Xiamen, 361021, China
8 9 10 11 12 13 14 15 16 17 18
19
20
21 1
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Abstract
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Passive samplers for moderately hydrophobic organic compounds (MHOCs) (i.e., log Kow
24
ranging from 2 to 5) are under-developed compared to those that target polar or strongly
25
hydrophobic compounds. The goal of this study was to identify a suitable polymer and
26
develop a robust and sensitive film-based passive sampler for MHOCs in aquatic systems.
27
Polymethyl methacrylate (PMMA) exhibited the highest affinity for fipronil and its three
28
metabolites (i.e., fipronils) (log Kow 2.4-4.8) as model MHOCs compared with polyethylene
29
and nylon films. In addition, a 30-60 min treatment of PMMA in ethyl ether was found to
30
increase its sorption capacity by a factor of 10. Fipronils and 108 additional compounds (log
31
Kow 2.4 - 8.5) reached equilibrium on solvent-treated PMMA within 120 h under mixing
32
conditions and their uptake closely followed first-order kinetics. PMMA-water partition
33
coefficients and Kow revealed an inverse parabolic relationship, with vertex at log Kow of 4.21
34
± 0.19, suggesting that PMMA was ideal for MHOCs. The PMMA sampler was tested in an
35
urban surface stream, and in spiked sediment. The results demonstrated that PMMA film,
36
after a simple solvent swelling treatment, may be used as an effective passive sampler for
37
determining Cfree of MHOCs in aquatic environments.
38 39
Keywords: Polymethyl methacrylate; moderately hydrophobic organic compounds;
40
equilibrium passive sampling; swelling treatment; partition coefficient (Kpw); fipronil
2
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INTRODUCTION
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Risk assessment and toxicity evaluation require a convenient and effective tool to
52
measure the freely dissolved concentration (Cfree) of hydrophobic organic compounds
53
(HOCs) in water and sediment, because Cfree characterizes chemical activity that is relevant
54
to chemical transport throughout different matrices and acute toxicity. Passive samplers
55
have found widespread use in measuring time-weighted average Cfree in aquatic
56
environments over the last two decades.1, 2 As polarity of organic contaminants spans from
57
ionic to strongly hydrophobic (i.e., log Kow > 5), various passive samplers have been
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proposed and tested for Cfree measurement.3, 4 Passive samplers composed of nonpolar
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polymeric sorbents, e.g., poly(dimethylsiloxane) (PDMS), low-density polyethylene (PE),
60
polyoxymethylene (POM) in thin film, sheet or fiber configurations, are compatible with
61
strongly hydrophobic compounds. Complementary passive samplers are available for polar
62
and ionizable chemicals, such as the polar organic chemical integrative sampler (POCIS),5
63
solid-phase adsorption toxin tracking (SPATT),6 polar organics version of Chemcatcher
64
and diffusion gradients in thin-films (o-DGT).7, 8 Based on their specific configurations,
65
passive samplers made of PDMS-coated fibers, or PE, POM or silicone film/sheets may be
66
used in both water and sediment and operated in the equilibrium or kinetic sampling mode.9
67
Passive samplers for moderately hydrophobic organic compounds (MHOCs) (i.e., log
68
Kow 2-5) are comparatively less developed, even though many emerging contaminants fall
69
into this classification.10 A few materials, including polyacrylate-coated SPME fiber, 11, 12
70
POM,13 and a customized plastic film poly(ethylenecovinylacetate-co-carbon monoxide) 3
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(PEVAC),14 were previously tested for MHOCs with some success. However, these
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samplers have drawbacks including slow diffusion rates of HOCs in POM, lack of
73
commercially produced PEVAC and disposable SPME fiber, and fragility of the SPME
74
fiber assembly.
75
The goal of this study was to develop a film-based sampler for Cfree determination of
76
MHOCs in aqueous matrices. Using the insecticide fipronil and its three biologically active
77
metabolites (log Kow 2.4-4.8) as model MHOCs, we undertook an investigation to first
78
evaluate different film types for their uptake capacities, and then optimize the selected
79
polymer film (polymethyl methacrylate, or PMMA) for equilibrium sampling. Additionally,
80
we discovered that pretreatment of PMMA film by swelling with solvents drastically
81
enhanced its capacity to absorb MHOCs.15, 16 A dataset of PMMA-water partition
82
coefficients (Kpw) for 112 organic compounds (Kow 2.4-8.5) was experimentally derived,
83
allowing the evaluation of relationships between Kpw and Kow. The derived method was
84
then successfully tested in situ for surface water under field conditions and ex situ for
85
sediment spiked with the model MHOCs.
86 87 88
EXPERIMENTAL SECTION The sampler development involved a series of step-wise experiments: 1) comparison of
89
PMMA, PE, and nylon-6 for their sorption capacities for fipronils as model MHOCs;17, 18 2)
90
enhancement of PMMA sorption capacity by a simple solvent swelling pre-treatment; 3)
91
determination of PMMA-water partition coefficients (Kpw) at equilibrium for fipronils and
92
a wide range of organic compounds (log Kow 2.4-8.5) for PMMA; and 4) application of the 4
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PMMA sampler in an urban stream to measure Cfree of fipronils in situ, and in spiked
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sediments to estimate Cfree in porewater ex situ. These experiments are briefly described
95
below.
96
Evaluation of film types for sorption of fipronils. Samples of PMMA (75 µm
97
thickness, Kaneka, Hyogo, Japan) and nylon-6 (25 µm thickness, Honeywell, Morristown,
98
NJ, USA) were cleaned in hexane, and then in deionized water by sonication (15 min × 3)
99
before use. Polyethylene film (25 µm thickness, Covalence, Minneapolis, MN, USA) was
100
cleaned in dichloromethane, methanol, and then deionized water by sonication (15 min × 3).
101
Fipronil, fipronil sulfone, fipronil sulfide, and fipronil desulfinyl (fipronils) (>98%,
102
AccuStandard, New Haven, CT, USA) were all found to be stable in water in the laboratory
103
in our preliminary test. However, to prevent interconversion, fipronil, and its three
104
degradates were separately spiked into water at 1000 ng/L in different containers in the
105
following experiments.
106
The spiked water was transferred to several 500-mL flat-bottom flasks. The flasks
107
were filled to minimize headspace and kept in the dark for 48 h. Prior to introducing the
108
film, the spiked water was mixed with a glass coated magnetic stir bar at 250 rpm for 2 h.
109
Three pieces of PMMA, PE or nylon film (0.035 g each) were added into each flask. All
110
flasks were then closed with ground-glass stoppers, wrapped in aluminum foil, and kept in
111
the dark at room temperature (22 °C). Preliminary experiments showed that the partition
112
between the film and water reached an apparent steady state after 72 h of equilibration for
113
all three film types. After 72-h exposure, the films were retrieved, rinsed with deionized
114
water, and air-dried. For analysis, recovery surrogates 4,4'-dibromooctoflurobiphenyl 5
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(DBOFB) and PCB208 (a polychlorinated biphenyl congener) were added and each
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PMMA film was extracted by sonication for 15 min (× 3) in hexane/methanol/acetone
117
(8:1:1, v/v). The nylon and polyethylene films were similarly extracted using
118
dichloromethane. The extract was concentrated and solvent-exchanged into hexane (1.0
119
mL). After the addition of the internal standard (PCB205) at 50 ng/mL, samples were
120
analyzed for fipronils. Preliminary tests showed that fipronils could be quantitatively
121
extracted from the films using the above extraction procedures, with recoveries > 75%.
122
Modification of PMMA by solvent swelling treatment. The above experiment
123
resulted in PMMA being the best film type for sampling fipronils from water.
124
Solvent-induced film swelling was attempted as a novel approach to further enhance the
125
sorption capacity of PMMA. From preliminary experiments, ethyl ether, methanol,
126
2-propanol and ethyl ether/methanol (1:1, v/v) mixture were selected for evaluation.
127
Pre-cleaned PMMA strips (2.2 by 2.2 cm, or 0.043 g each) (n=3) were soaked in one of the
128
solvents for 30, 60, 120, 240, or 360 min at the room temperature. After air-drying
129
overnight, the solvent-treated PMMA samples were found to return to the original weight,
130
suggesting that residual solvent was completely evaporated from the film. The
131
solvent-treated films were similarly tested in fipronil-spiked water to determine their
132
sorption capacities. Pre-cleaned PMMA film without solvent treatment was included as the
133
control.
134
Topographic images of PMMA film before and after the solvent swelling treatment
135
were taken using an atomic force microscope (AFM) (Dimension 5000, Veeco Instruments,
136
Plainview, NY, USA), from which Mean Roughness (Ra) and surface area were measured. 6
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The Ra is the arithmetic average of the absolute values of the profile height deviations from
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the mean in a selected region. The surface area is the three dimensional area of a selected
139
region.
140
Determination of equilibrium time and Kpw. Ethyl ether-treated PMMA pieces (2.5
141
by 1.3 cm, or 0.028 g each) were used to derive Kpw for fipronils and a suite of 108
142
chemicals (log Kow 2.4 - 8.5), including musk ketone, galaxolide, pyrethroid insecticides,
143
polycyclic aromatic hydrocarbons (PAHs), PCBs, organochlorine pesticides (OCPs), and
144
polybrominated diphenyl ethers (PBDEs) (see Supporting Information for a complete list of
145
compounds). The exposure setup was similar to that used in above sorption experiment. A
146
flask containing the spiked water and a stir bar served as “no film” control. At 2, 4, 8, 12,
147
24, and 48 h for the fipronils, or 4, 8, 12, 24, 36, 48, 96, and 120 h for the 108 chemicals, a
148
single flask was sacrificed, and PMMA strips (n=3) were collected and extracted as
149
described above. The water phase was liquid-liquid extracted for three times using
150
dichloromethane (40 mL) and the extract analyzed to quantify the mass balance and derive
151
Cfree for the calculation of Kpw. The recovery surrogates and internal standard were used for
152
quality control.
153 154
At equilibrium, Kpw was calculated using Cfree, ��� =
�����
(1)
� ��
155 156
The analyte uptake profile could be described by the first-order kinetics equation19
157 158
��� =
� �� ��
�
× (1 − � ��×� ) 7
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with
161
�=
162
�� �� �! ��
=
��
�� �� ��
+ #$
(3)
163 164
where %& is the initial aqueous concentration, CPMMA is the concentration (ng/L) on film
165
at time t, k1 (1/h) is the uptake rate constant, k2 (1/h) is the elimination rate constant, Vp is
166
the polymer volume of film, Vw is the volume of water, and t is the contact time (h)
167
between the film and analyte in the aqueous phase. Regression analysis using the
168
time-series data would yield k1 and k2, from which Kpw may be further calculated as,
169 �
��� = ��
170
(4)
!
171 172 173
Equilibrium time of passive sampling was defined as the time needed to reach 90% of equilibrium (t90%),20
174
'(&% =
175
*+,&
(5)
�!
176 177 178 179 180
Regression analyses were performed by SPSS (version 19.0) for Windows (IBM, Armonk, NY, USA). Applications for Water and Sediment Sampling. The PMMA samplers (14 by 5.3 cm or ~0.67 g each) were prepared, including swelling by ethyl ether, as described above. 8
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The PMMA samplers were deployed in the surface water for 2 d at a location in San Diego
182
Creek in Irvine, California (33º 39’ 19.20” N, 117º 50’ 43.13” W) that drains an urban
183
watershed. The samplers were suspended at 20 cm from the surface, using copper wire
184
mounted on a weight. On day 0, 1, and 2, water was collected into two 1-L amber glass
185
bottles. The film sampler was retrieved at the end of 2 d deployment. The samples were
186
transported to the laboratory on ice, and immediately analyzed for fipronils to measure
187
CPMMA on the PMMA, and total concentration (Ctotal) in the grab samples by liquid-liquid
188
extraction with methylene chloride (without filtration). The Cfree was calculated from
189
CPMMA using Eq. 1. Water flow velocity was measured at the sampling site once a day from
190
deployment to retrieval during the sampling event. Dissolved organic carbon (DOC) was
191
determined to be 33.2 ± 10.3 mg/L after analysis of sample aliquots on a Shimadzu
192
TOC-VCSH analyzer (Kyoto, Japan).
193
A batch experiment was further conducted to evaluate the application potential of
194
PMMA samplers in sediment. A sediment sample was collected from Dana Point,
195
California. The sediment contained 0.63% total organic carbon (TOC) with a textural
196
composition of 26.1% sand, 66.2% silt and 7.8% clay. Four subsamples of the sediment
197
were separately spiked with each fipronil compound. The spiked sediment samples in glass
198
jars were rotated on a roller for 24 h after spiking, and stored at 4 ºC and rolled 2 h once per
199
week for 28 d to achieve uniform distribution and phase equilibrium.22 The bulk
200
concentration was measured to be 11.6 µg/kg for fipronil, 62.4 µg/kg for fipronil desulfinyl,
201
35.5 µg/kg for fipronil sulfide, and 67.2 µg/kg for fipronil sulfone on a dry weight basis.21
202
Twelve pieces of pre-treated PMMA film (1.8 by 1.8 cm, or 0.028 g each) were inserted 9
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into the spiked sediment (300 g, wet weight) in a glass jar and the samples were rotated at
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60 rpm at the room temperature. Three PMMA films were retrieved from the sediment at 4,
205
6, 10, and 16 d after the sampler placement and analyzed for fipronils on the PMMA film,
206
from which Cfree was calculated using the derived Kpw in Eq. 1.
207
Instrumental analysis and quality assurance/quality control. The final extracts
208
were analyzed on a gas chromatography/mass spectrometry system (GC/MS) (Agilent
209
7890GC/5975C MS, Wilmington, DE). Detailed instrument conditions are given in the
210
Supporting Information. All analytical data were subjected to strict quality
211
assurance/quality control. Procedural blanks, matrix spike (standards spiked into matrix,
212
e.g., PMMA and water), and sample triplicates were used. No detectable target analytes
213
were found in the procedural blanks. The overall recoveries (PMMA and water) in the
214
batch experiments were >75%, indicating acceptable mass balances.23 Overall mean
215
recoveries of surrogate standards were 62-97% (DBOFB) and 82%-105% (PCB208) for the
216
extraction of PMMA samplers, water, and sediment under the used conditions.
217 218 219
RESULTS AND DISCUSSION Selection of suitable polymer. Among the three polymer films evaluated in this study,
220
PMMA consistently absorbed an order of magnitude more fipronil compounds than
221
polyethylene or nylon film (Fig. S1), suggesting that PMMA has a higher affinity for
222
fipronils under the same conditions. Even though nylon contains the polar amide bond, it
223
did not show superiority over PMMA in the sorption of fipronils. This may be attributed to
224
two factors. The relative density of the polar group in nylon that has 4 and 6 methylene 10
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groups between the amide groups on the repeating unit is lower than that in PMMA that has
226
only 2 methylene groups. The position of the amide bond in nylon also makes it spatially
227
less accessible for the target molecule, as compared to the pendant ester bond in the PMMA
228
structure.24
229
Enhanced sorption after solvent treatment. To explore possibilities for further
230
enhancing the sorption of MHOCs, pre-cleaned PMMA film was subjected to swelling
231
treatment by solvents. As shown in Fig. 1, sorption of fipronils by PMMA increased
232
dramatically after contact in ethyl ether or isopropanol for 30 min. In particular, the
233
treatment with ethyl ether increased the sorption by approximately tenfold. In contrast,
234
swelling in methanol did not appreciably increase sorption of fipronils, while treatment in
235
methanol/ethyl ether (1:1, v/v) only caused a limited increase. The treatment with ethyl
236
ether or isopropanol appeared to have resulted in relatively higher standard deviationsas
237
compared to the methanol or methanol/ethyl ether treatment (Fig 1). I
238
An additional test was carried out by extending the solvent treatment to 6 h in ethyl
239
ether. The sorption increases were similar when the treatment time was 30 or 60 min, but
240
no significant additional enhancement was observed when the solvent exposure time was >
241
2 h. Consequently, contact in ethyl ether for 30 to 60 min was considered to be effective for
242
maximizing the sorption capacity of PMMA samplers.
243
To the best of our knowledge, this was the first attempt to use solvent swelling to
244
enhance the performance of passive samplers.16, 25 Given that sorption of polymer-based
245
membranes or fibers is often low for polar or MHOCs, solvent pretreatment may be a
246
highly viable solution to developing more efficient passive samplers. 11
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Atomic force microscopic images of PMMA film before and after 30-min ethyl ether
248
treatment showed distinct differences in the membrane’s surface topography (Fig. 2). The
249
PMMA film after solvent treatment showed a uniform and consistent texture. The Ra of the
250
PMMA film increased from 2.32 to 9.44 nm; however, the surface area was only expanded
251
slightly, from 1.07 to 1.12 cm2 cm-2. Therefore, sorption enhancement of PMMA film after
252
the solvent treatment was likely attributable to enhanced absorption into the polymer rather
253
than adsorption.15, 26, 27
254
It was argued that sorption material used for equilibrium passive samplers should
255
have a lower glass transition temperature (Tg) than the ambient temperature of sampling.14
256
This is true for the rubbery polymers such as PDMS, PE, POM and PEVAC that have very
257
low Tgs (< 0 ºC). However, PMMA is a glassy polymer with Tg about 110 ºC. During
258
solvent swelling treatment, it is likely that solvent molecules diffused into the film and
259
relaxed the polymer structure, creating and expanding voids for organic molecules to
260
diffuse into the polymer phase.27, 28 Penetration of organic solvents through PMMA was
261
previously characterized using several instruments including AFM, laser interferometry,
262
ellipsometer, fluorescent force-sensitive and quartz crystal microbalance.29, 30 Using
263
fluorescence analysis, Mayer et al.31 and Magner et al.14 demonstrated that sorption of
264
fluoranthene into PDMS and PEVAC was due to absorption, instead of adsorption.
265
Kpw values for MHOCs. The uptake time series for fipronils by the PMMA film
266
showed apparent equilibrium in 24 h under mixing conditions (Fig. 3). The Kpw values were
267
subsequently calculated using Eq. 1 with averages of data at 24 and 48 h (Table 1). The
268
CPMMA versus the exposure time fitted well to Eq. 2 (R2 = 0.83-0.87), allowing the 12
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estimation of Kpw values from Eq. 4. Both methods gave identical Kpw values, confirming
270
that the sampling reached equilibrium in 24 h. The average t90% was estimated to be 16 ± 2
271
h for fipronil compounds under the experimental conditions. The log Kpw values estimated
272
from the curve fitting were used in the following experiments for calculating Cfree, because
273
of their relatively smaller standard deviations and the fact that the whole time series was
274
used in deriving the values.
275
The average log Kpw of fipronils was 3.37 ± 0.32, as compared to their average log Kow
276
value of 3.44 ± 0.97 (Table 1) and average (excluding fipronil desulfinyl) log Kpw of 4.34 ±
277
0.31 for polyacrylate-coated (85 µm thickness) SPME fiber. 18 The Kpw values were
278
similarly derived for the entire list of organic compounds considered in this study (Table
279
S1). The fit of data was generally good, with average R2 of 0.89 ± 0.07. Therefore, sorption
280
of HOCs onto PMMA closely followed first-order kinetics, which is in agreement with that
281
observed with other equilibrium passive samplers, including PDMS fibers and polyethylene
282
membranes.4 32 The t90% ranged from 11 to 120 h for the tested chemicals under the
283
experimental conditions. Considering the wide range of log Kow (2.4 to 8.5), the relatively
284
short equilibrium time implies that the solvent-treated PMMA may be suitable for
285
equilibrium sampling of a large number of HOCs, including those that are strongly
286
hydrophobic. The short equilibrium time offers several advantages. As sampling may be
287
done under equilibrium conditions, it eliminates the need for using approaches such as
288
performance reference compounds to account for non-equilibrium sampling.33 The short
289
sampling time is highly desirable for less stable compounds, such as those that have
290
relatively short half-lives due to rapid hydrolysis or photolysis.34 13
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Plots of log Kpw versus log Kow (Fig. 4a), and (log Kow - log Kpw) versus log Kow (Fig.
292
4b) gave parabolic curves. Good correlation between log Kpw and log Kow were obtained
293
with a very high R2 (0.97) and a small standard error (0.19) for the entire list of chemicals
294
(N = 112):
295
log �0% = −0.10 (log �3% )$ + 1.08 log �3% + 1.28
296
(6)
297 298
In contrast, linear relationships were observed between log Kpw and log Kow on rubbery
299
polymers (e.g., PDMS, PE, POM and PEVAC) in previous studies for given Kow ranges.13,
300
14, 35, 36
301
or log Kpw 4.20 ± 0.19, suggesting that sorption of PMMA for HOCs increased with
302
increasing hydrophobicity until approximately log Kow of 5.40. For highly hydrophobic
303
compounds with log Kow > 5.40, PMMA enrichment factor declined with increasing log
304
Kow. The maximum log Kpw value (i.e., 4.20 ± 0.19) appeared to be the enrichment
305
limitation of the PMMA film.
306
The vertex of the log Kpw versus log Kow curve (Fig. 4) was found at log Kow ~ 5.40
The term (log Kow - log Kpw) increased monotonically with respect to log Kow. At log
307
Kow 4.0, log Kpw equaled to log Kow. When log Kow was < 4.0, log Kpw was greater than log
308
Kow, indicating that less hydrophobic compounds tended to diffuse more favorably into the
309
solvent-treated PMMA membrane than into n-octanol. This observation clearly suggests
310
that PMMA is a good sorbent polymer for sampling MHOCs, and has advantages over the
311
other materials due to its high enrichment factors and short equilibrium times.
312
The nonlinear relationship of log Kpw versus log Kow may be attributed to several 14
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factors, such as non-equilibrium, poor mass balances, chemical instability, unaccounted
314
chemical losses due to sorption to container surfaces, and intrinsic properties of PMMA
315
and analytes.36, 37 As both aqueous phase and PMMA film were simultaneously analyzed
316
for the target analytes in this study, which eliminated the influence of most of the listed
317
factors, the curvilinear relationship was most likely caused by physicochemical properties
318
of both PMMA and analytes. Unlike the rubbery polymers, the glassy PMMA film has
319
relatively rigid network with small cavities. Even though the PMMA film underwent
320
solvent swelling, formation of cavities and interactions of organic molecules with the
321
cavities in the PMMA film would require energy. Difference of equilibrium constants (log
322
Kow - log Kpw) may be deduced from the Gibbs free energy relationship using the following
323
equation. 37
324 325
log �6� − log ��� = (∆89:; @6AB:=
