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BAs deposited in the bay catchment likely enter rivers and provide an ... Pallas is also an Arctic Monitoring and Assessment Program (AMAP) station. ...
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Atmospheric Transport and Deposition of Bromoanisoles Along a Temperate to Arctic Gradient Terry F. Bidleman, Eva Brorström-Lundén, Katarina Hansson, Hjalmar Laudon, Olle Nygren, and Mats Tysklind Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.7b03218 • Publication Date (Web): 08 Sep 2017 Downloaded from http://pubs.acs.org on September 10, 2017

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Environmental Science & Technology is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

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Environmental Science & Technology

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Atmospheric Transport and Deposition of Bromoanisoles

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Along a Temperate to Arctic Gradient

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Terry F. Bidleman1*, Eva Brorström-Lundén2, Katarina Hansson2, Hjalmar Laudon3,

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Olle Nygren4, Mats Tysklind1

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Department of Chemistry, Umeå University, SE-901 87 Umeå, Sweden; 2Swedish

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Environmental Research Institute (IVL), Aschebergsgatan 44, SE-411 33 Gothenburg, Sweden;

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Department of Forest Ecology and Management, Swedish University of Agricultural Sciences

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(SLU), SE-901 83 Umeå, Sweden; 4Building Office, Umeå University, SE-901 87 Umeå,

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Sweden.

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*E-mail: [email protected], phone (mobile): +46-72-510-1254

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Abstract Bromoanisoles (BAs) arise from O-methylation of bromophenols, produced by marine algae

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and invertebrates. BAs undergo sea-air exchange and are transported over the oceans. Here we

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report 2,4-DiBA and 2,4,6-TriBA in air and deposition on the Swedish west coast (Råö) and the

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interior of arctic Finland (Pallas). Results are discussed in perspective with previous

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measurements in the northern Baltic region in 2011-2013. BAs in air decreased from south to

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north in the order Råö ˃ northern Baltic ˃ Pallas. Geometric mean concentrations at Pallas

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increased significantly (p 2.5, we assumed PUF/air equilibrium and calculated the air concentration from:

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Equilibrium sampling: CA = KPA/CPUF

VS/VB > 2.5

(1)

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where CA and CPUF and KPA have units of pg m-3 air, pg g-1 PUF and m3 g-1, respectively.

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When VS/VB ≤ 2.5, the breakthrough level b was estimated as described in Supporting

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Information and the air concentration was calculated from the mass of analyte collected by the

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PUF (QPUF), the sampled air volume VS and 1-b:

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Non-equilibrium sampling: CA = QPUF/[VS*(1-b)]

VS/VB ≤ 2.5

6 ACS Paragon Plus Environment

(2)

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Environmental Science & Technology

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Most Råö samples were collected under equilibrium conditions, due to the high air volumes and

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relatively warm temperatures (Table S1). A few non-equilibrium events occurred in winter-early

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spring. The frequency of these was greater at Pallas and only summer samples were collected

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under equilibrium conditions (Table S2).

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3. Results and Discussion

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3.1. Atmospheric concentrations

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BAs were above the LOD in every sample analyzed. Mean and geometric mean (GM)

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concentrations of 2,4-DiBA and 2,4,6-TriBA in air at Råö and Pallas are summarized in Table 1

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and details for each sample are given in Tables S1 and S2. Discontinuities in the biweekly or

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monthly records are due to missing samples. We also identified 2,6-DiBA at about 10% of 2,4-

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DiBA concentrations, but quantitative results are not reported. 2,6-DiBA is more volatile than the

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other DiBAs56 and its KPA has not been determined. Searches for 2,5- and 3,5-DiBA were

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negative, as in our previous Baltic study.43

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Temporal trends of BAs at Råö and Pallas during each year of observation are shown in

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Figures S2 and S3. Annual mean concentrations at Råö ranged from 20 ± 9.1 to 41 ± 20 pg m-3

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for 2,4-DiBA, and 43 ± 20 to 74 ± 36 pg m-3 for 2,4,6-TriBA. Annual means at Pallas ranged

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from 3.7 ± 4.4 to 20 ± 23 pg m-3 for 2,4-DiBA and 4.9 ± 5.5 to 14 ± 12 pg m-3 for 2,4,6-TriBA.

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GM concentrations of 2,4-DiBA and increased significantly at Pallas between 2002-2015 (p =

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0.041), while an increasing trend was also suggested for 2,4,6-TriBA, but was not significant (p =

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0.064).

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The trends in Figures S2 and S3 are summarized in Figure 3a, derived as follows. Monthly

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concentrations in each year (5 years at Råö, 7 years at Pallas) were expressed as percentages of

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the peak month concentrations and these percentages were averaged over the years.

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Concentrations of both BAs at Råö rose smoothly from spring to midsummer and remained near

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peak until December, when they dropped sharply and remained low until March. Mean trends 7 ACS Paragon Plus Environment

Environmental Science & Technology

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were different at Pallas. BA concentrations rose from May, peaked in September, and remained

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high through December for 2,4,6-TriBA while dropping for 2,4-DiBA. Lowest concentrations for

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both BAs occurred in March-April. Proportions of the two BAs (Figure 3b) are discussed in

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Section 3.3.

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BAs in air were previously measured by deploying passive samplers over 3-4 months at

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northern Baltic island stations Holmön (HOL, 63.79 oN, 20.84 oE ) and Haparanda Sandskär

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(SKR, 65.57 oN, 23.75 oE) and at Krycklan Catchment (KRY, 64.23 oN, 19.77 oE), about 60 km

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inland, and active air samples were also collected during short-term campaigns on HOL.51 Mean

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concentrations of 2,4-DiBA and 2,4,6-TriBA were 23 ± 16 and 43 ± 30 pg m-3 at HOL, 19 ± 13

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and 18 ± 7.9 pg m-3 at SKR, and 38 ± 19 and 23 ± 8.9 pg m-3 at KRY (Table 1). Mean ± SD

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concentrations at the five sites between 2012-2015 are summarized in Figure 2 and show a

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general decrease northward with Råö > HOL ≈ KRY > SKR > Pallas. Others have reported BAs

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in air along the Norwegian coast. Concentrations in air at Lista (58.10 oN, 6.57 oE) in 2003 were

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19 ± 12 pg m-3 for 2,4-DiBA and 13 ± 9 pg m-3 for 2,4,6-TriBA.49 2,4,6-TriBA was measured at

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Birkenes (58.38 oN, 8.25 oE) from 2007-2014 (3.3 – 5.0 pg m-3) and Andøya (69.28 °N, 16.01

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°E) from 2010-2014 (2.8 – 5.7 pg m-3).38,39 Levels over the North and South Atlantic in 1993 and

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1999-2000 ranged from 0.2 – 7 pg m-3 for 2,4-DiBA, 0.4 – 3.6 pg m-3 for 2,6-DiBA and 0.5 – 42

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pg m-3 for 2,4,6-TriBA .4,45,46 Means over the Canadian Arctic Archipelago in 2007-2008 were 15

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± 10 pg m-3 for 2,4-DiBA and 20 ± 14 pg m-3 for 2,4,6-TriBA.48

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Temperature relationships are examined for plotting the logarithm of partial pressure (log

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P/Pa) versus 1/T (K). Regressions at Råö are significant for each year (p