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Environmental Processes
Organotin Release from Polyvinyl Chloride (PVC) Microplastics and Concurrent Photodegradation in Water: Impacts from Salinity, Dissolved Organic Matter and Light Exposure Chunzhao Chen, Ling Chen, Ying Yao, Francisco Artigas, Qinghui Huang, and Wen Zhang Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.9b03428 • Publication Date (Web): 12 Aug 2019 Downloaded from pubs.acs.org on August 16, 2019
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Organotin Release from Polyvinyl Chloride (PVC) Microplastics
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and Concurrent Photodegradation in Water: Impacts from Salinity,
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Dissolved Organic Matter and Light Exposure
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Chunzhao Chen,a,e Ling Chen,b,c Ying Yao,d Francisco Artigas,d Qinghui Huang,a,c Wen Zhang e*
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a Key
Laboratory of Yangtze River Water Environment of the Ministry of Education, College of
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Environmental Science and Engineering, Tongji University, Shanghai, China
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b Shanghai
Institute of Pollution Control and Ecological Security, Shanghai, China.
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c State
Key Laboratory of Pollution Control and Resource Reuse, College of Environmental Science and
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Engineering, Tongji University, Shanghai, China.
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d
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Environmental Research Institute, Lyndhurst, New Jersey, USA
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e John
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Technology, Newark, New Jersey, USA.
Rutgers University Newark, Department of Earth and Environmental Science, Meadowlands
A. Reif, Jr. Department of Civil and Environmental Engineering, New Jersey Institute of
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Corresponding author:
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Wen Zhang. Phone: +1- (973) 596-5520; Fax: (973) 596-5790; Email:
[email protected] 1 ACS Paragon Plus Environment
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Abstract
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Photochemical weathering leads to degradation of microplastics and releases chemical
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additives, polymeric fragments and/or byproducts. This study evaluated the release kinetics of
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organotin compounds (OTCs) from three different sized (10-300 µm) polyvinyl chloride (PVC)
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microplastics under UV and visible light irradiation. Four OTCs, dimethyltin (DMT),
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monomethyltin (MMT), dibutyltin (DBT) and monobutyltin (MBT), were found to release from
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PVC particles after 24-h leaching in darkness ranging from 2 to 20 µg·g-PVC-1. Under
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UV/visible light irradiation, only DMT and DBT were detectable, whereas MMT and MBT were
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not detected due to rapid photodegradation. The total tin concentrations (including organic and
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inorganic tins) in the aqueous phase monotonically increased under light exposure. By contrast,
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they reached plateaus after 24 h in darkness, confirming the photodegradation of OTCs. A
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release kinetics model was established and correctly interpreted the microplastics size effect on
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OTC release process. Finally, the impacts of salinity and dissolved organic matter (DOM) were
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investigated. The release and photodegradation of OTCs were both inhibited at high salinity
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conditions, probably due to the enhanced re-adsorption of OTCs on PVC microplastics and the
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formation of halogen radicals that were less reactive towards neutral OTCs. The presence of
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DOM, however, increased OTCs release probably because excited state triplet DOM (3DOM*)
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formed and reacted with OTCs from PVC microplastics.
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Keywords: Organotins; PVC microplastics; Photodegradation; Reactive radicals; Salinity; DOM;
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1. Introduction
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Weathering or aging of microplastics leads to the release of a variety of chemicals, additives,
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polymeric fragments and ultrafine particles (e.g., nanoplastics). For instance, phthalate is a
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typical plasticizer used to soften polyvinyl chloride (PVC)-based materials. Tricolosan is
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commonly applied as antimicrobial agent in plastic toys and trash bags 1. Besides chemical
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additives, monomers such as propylene oxide, bisphenol A, styrene and vinyl chloride can be
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released from weathered plastics
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carcinogens, therefore causing potential harmful effects on organisms 3. Microplastics in natural
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waters are likely to undergo complex interactions with aquatic species (e.g., bacteria, algae,
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mammals) and hydrophobic pollutants
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adsorption and desorption behavior of organic pollutants and heavy metals on microplastics
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Nevertheless, the environmental fate of released chemical additives or degradation byproducts
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from microplastics has not been well understood.
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2, 3.
These plastic leachates may be endocrine disruptors and
4, 5.
Previous studies have mainly focused on the 6-8.
Organotin compounds (OTCs) are one of the man-made organometallic derivatives with 9, 10.
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endocrine disrupting effects
Besides as biocides and fungicides, OTCs have been used as
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light and thermal stabilizers in PVC plastics for more than 40 years, accounting for 3.5% of the
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total tin consumption worldwide 11. Meanwhile, PVC polymers have broad applications in pipes,
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hoses, toys, medical devices and automotive parts and account for about 73% of the annual
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global production of plasticizers (e.g., phthalate, benzophenones and also OTCs)
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waste PVC or its debris may enter the environment and contribute to the release of embedded
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chemicals. Some studies have reported the release behavior of diethylhexyl phthalate (a type of
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plasticizer) from PVC-based products
15, 16.
12-14.
Thus,
However, there is a paucity of information on the
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release process of OTCs from PVC materials, which is important for understanding the
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environmental fate and potential impacts of microplastics.
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Photochemical weathering of microplastics in natural waters such as estuaries and oceans
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may experience impacts from transiting salinity or dissolved organic matter (DOM). The
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seawater-specific halide ions have been considered as hydroxyl radicals (•OH) scavengers (i.e.,
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•OH + Br- → Br•+OH-) and can also drive the decomposition of organic contaminants
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Compared to freshwater conditions, reactive halogen radicals (RHS) in marine waters increase
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the radical-mediated oxidation rates by 1-2 orders of magnitude and increase overall
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photodegradation rates up to five-fold
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enhanced degradation of organic contaminants (e.g., dimethyl sulfide and dienes) by halogen
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radicals in seawater. On the other hand, photochemical degradation of organic pollutants and
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micro-polymers not only depends on the direct absorbance of light irradiance, but also the levels
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of DOM since some reactive intermediates of DOM may directly or indirectly react with organic
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chemicals 21.
18, 19.
For instance, Parker et al.
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17.
have reported the
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This study investigated OTC release kinetics from PVC microplastics in simulated seawater
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under UV or visible light irradiation. Three different sizes of PVC microplastics were prepared
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and rigorously characterized. We compared the release kinetics of OTCs from these PVC
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microplastics and attributed the photochemical weathering and the OTC release to the photo-
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induced information of hydroxyl radicals that were experimentally measured. A new kinetics
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model was established to analyze the microplastic size effect on the release kinetics. The
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modeling analysis is also aimed to provide a quantitative assessment of the contributions from
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surface desorption and photodegradation in the release kinetics of OTCs. Furthermore, the
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influences of photo-induced reactive intermediates (i.e., Cl•, Br•, ClBr•- and 3DOM*) on OTCs
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release and photodegradation were also investigated under UV irradiation. These results are
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expected to provide new insight into the weathering process of microplastics and their potential
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hazardous effects in natural water environment.
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2. Materials and Methods
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2.1. Materials
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Three different sized PVC microplastics were prepared by grinding the PVC thin sheet and
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sieving (Fig. S1) in the Supporting Information (SI). The artificial seawater (20 ‰ of salinity)
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used in OTC release experiments contained 312 mM NaCl and 0.312 mM NaBr since the
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chloride (Cl-) concentrations in natural marine waters are about thousand times higher than
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bromide (Br-)
17, 22.
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NaBr) were prepared to investigate the halogen radical influences on OTC release and
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photodegradation. Humic acid (Sigma-Aldrich, CAS No.1415-93-6) was used as a DOM
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surrogate. A UV lamp (365 nm; UVP, UVL-21, Analytik Jena, Upland, CA) and a LED lamp
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(400 nm, BLCC-04, Prizamix) were used to provide light irradiation at 2.0 W·m-2 and 1.5 W·m-2,
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respectively.
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2.2. Characterization of PVC Microplastics
Reaction solutions with different halide ion concentrations (i.e., NaCl and
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Surface morphology of PVC microplastics was examined by a Scanning Electron
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Microscopy-Energy Dispersive Spectrometer (SEM-EDS; JSM-5610LV, JEOL, Japan), which
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also determined the element abundance on PVC microplastic surfaces. The diameter distribution
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was analyzed from the SEM images using the ImageJ software. The specific surface areas were
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determined by the Brunauer-Emmett-Teller (BET) method using a Micromeritics analyzer
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(Autochem Ⅱ 2920). The zeta potential of microplastics was measured by a dynamic light
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scattering (DLS) with a Malvern Zetasizer (Nano ZS, Malvern Instruments, UK). The surface
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functional groups were examined by attenuated total reflection-Fourier Transformation Infrared
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Spectroscopy (ATR-FTIR, Cary 660, Agilent Technologies, the USA) with non-destructive
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determination of sample surfaces. Three replicate spectrums of each sample were collected at 64
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scans over the range of 4000-400 cm-1. Analysis for the treated samples was performed after
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being dried in a dark desiccator.
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Hydroxyl radicals (•OH) in UV-irradiated PVC suspension were detected using terephthalic
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acid (TA) as the probe molecules, which forms a highly fluorescent product, 2-
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hydroxyterephthalic acid (2-HTA). Briefly, 0.15 g of PVC microplastics was mixed with 150 mL
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of the 0.5 mM TA solution (previously dissolved in 2 mM NaOH) and irradiated by UV365 to
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induce the hydroxylation reaction of TA by •OH radicals, which occurs when the TA
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concentration is below 10-3 M at room temperature
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withdrawn every 30 min for 1.5 h and filtered through a 0.45-µm membrane filter before the
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analysis on a fluorescence spectrophotometer (F-4500, HITACHI, Japan). 2-HTA was identified
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at the emission wavelength of approximately 425 nm under an excitation wavelength of 315 nm.
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The UV-visible light absorption spectrum of PVC microplastics in artificial seawater was
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recorded in the range of 300-500 nm using a UV-Visible spectrophotometer (Evolution 201,
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Thermo Scientific).
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2.3. Release experiment design
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2.3.1. Release kinetics of organotins from PVC microplastics
23, 24.
About 1 mL of liquid samples was
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To examine the release of OTCs from PVC microplastics, 2 g of PVC microplastics and 500
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mL artificial seawater were added into a glass beaker and stirred under UV (365 nm) or visible
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light (400 nm) radiation (Fig. S2). Dark controls were exposed to the same conditions except
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with no light irradiation. At different time intervals (0.5, 1, 2, 5, 8, 16, 24, 32, 40 and 56 h), 7.5
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mL of water solution were withdrawn and filtered through a 0.22-μm glass fiber membrane
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(Thermo Fisher Scientific, the USA). 5 mL of filtrate were used to measure the OTC
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concentrations, and the remaining 2.5 mL were kept in refrigerator (4 ℃) for the total tin analysis.
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The liquid-to-solid ratio in reaction solutions changed more than 10% during the sampling
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procedure, which was considered in the subsequent data analysis. Prior to the release
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experiments, OTC determination was also carried out on pristine PVC microplastics to
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investigate how many amounts of OTCs attached on PVC surfaces.
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2.3.2. Effects of halide ions and DOM on organotin release from PVC microplastics
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Considering that OTC amounts leached from large PVC microplastics were relatively low,
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only small and medium sized PVC microplastics were used in this experimental assessment.
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Briefly, 0.1 g of PVC microplastics were added in 25 mL DI water with various amounts of Cl-
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and Br- ions as well as with/without 10 mg·L-1 of humic acid. Then, this solution was exposed to
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the UV365 irradiation for 24 h, followed by measuring the concentrations of dissolved OTC and
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total tin as mentioned above.
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2.4. Analytical detection
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2.4.1. Determination of the total surface OTCs on PVC microplastics
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To determine the total OTC contents on PVC microplastics (g-OTC·g-PVC-1), 50 mg of
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microplastics were mixed in 10 mL of methanol solutions containing 10% acetic acid and 0.03%
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tropolone, followed by a 30 min ultrasonic extraction and then 5 min centrifugation (1000×g). 5
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mL of supernatant was collected and spiked into 40 mL of a sodium acetate/acetic acid buffer
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(pH 4.5, 1 mol L-1) with addition of 1 g of NaCl, 4 mL of hexane, 0.1 mL of TPrT (as internal
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standard) and 600 μL of NaBEt4 (w/w=1%). The mixture was horizontally shaken for 1 h. Then,
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2 mL of organic phase was passed through a purification column filled with Florisil (500 mg/6
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mL, CNW) and eluted with 5 mL of hexane and diethyl ether (v/v=9:1). After concentrated to
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0.5 mL via nitrogen gas, OTCs were determined by gas chromatography-mass spectrometer
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(GC-MS).
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OTC determination and quantification were performed on an Agilent 5973-6890 GC-MS
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(USA) using a HP-5 capillary column. The injection was made in the split-less mode at 280 °C,
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and ion source was kept at 230 °C. The oven temperature started at 35 °C during the first 2 min,
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followed by a 10 °C·min-1 increase to 200 °C and held for 5 min. Mass spectrometer was
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operated in selected ion monitoring (SIM) mode with at least three qualified ions. High purified
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helium gas (99.99%) was used as GC carrier gas at a flow of 1 mL·min-1.
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2.4.2. Organotin determination in the aqueous phase of the water suspension of PVC
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5 mL of filtered water sample were mixed with 0.2 mL of an internal standard (TPrT, 1
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mg·L-1) in a 60 mL glass tube, followed by addition of 20 mL of a sodium acetate/acetic acid
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buffer (1 mol·L-1, pH 4.5), 2 mL of n-hexane and 600 μL of NaBEt4 solution (1%, w/w) as the
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derivatization agent. Then, they were horizontally shaken for 1 h for complete derivatization.
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After standing for 30 min, 1 mL of hexane phase was taken and subjected to the GC-MS analysis
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as mentioned above. For each batch (12 samples), 5 mL of blank seawater sample and 5 mL of
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OTC standards (50 μg·L-1) were also determined as quality check (QC) to ensure analytical
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system stability and no contamination during sample preparation.
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2.4.3. Total tin determination in the aqueous phase of the water suspension of PVC
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2.5 mL of filtered water samples were microwave digested using 2 mL HNO3 and 0.5 mL
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HCl and then diluted to 10 mL by DI water. The total tin concentrations were determined by
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Inductively Coupled Plasma-Mass Spectrometry (ICP-MS, Agilent 7700, the USA). One of the
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isotope tin, 118Sn, was selected for quantification based on its smaller analytical interference and 9 ACS Paragon Plus Environment
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larger sensitivity. The analysis sequence was as one reagent blank (0.2% of HNO3) and several
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samples by turns, and at the end tin standard was analyzed.
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2.5. Kinetics modeling of coupled release and photodegradation of organotins from PVC
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microplastics The concentration change (
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dC ) of released OTCs in the bulk solution (µg∙L-1∙h-1) is related dt
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to the release rate of OTCs from PVC microplastics and their subsequent photodegradation rate.
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As shown in Eq. 1-2, we hypothesized that (1) OTC release rate is proportional to its surface
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coverage on PVC microplastics; (2) OTC photodegradation follows a first order kinetics with its
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solution concentration and (3) the reduction rate of OTC-covered PVC surfaces exponentially
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decreases with time. All the parameters used for this model are listed in Table 1.
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V
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A(t ) Ao exp(k3t )
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where V is the volume of reaction solution (L); C is the remaining concentration of OTCs (µg·L-1)
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in the aqueous mixed with PVC microplastics at release time, t; k1 is the specific release rate
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constant of OTCs (µg·m-2·h-1); A(t) is the available surface area (m2) that still release OTCs at
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time, t; k2 is the first-order photodegradation rate constant of OTCs (h-1). A0 is the initial surface
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area of PVC microparticles which could be calculated from the BET results. k3 is a decrease rate
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constant for A(t) (h-1). k1 and k3 are correlated via the surface coating or coverage density (S) (i.e.,
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k1 S k3 ), where S indicates the quantity of OTCs per unit surface areas of PVC microplastics
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(µg∙m-2). Thus, rearranging Eq. 1 and Eq. 2 leads to:
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dC SAok3 exp(k3t ) k2C dt V
dC k1 A(t ) k2CV dt
(Eq. 1)
(Eq. 2)
(Eq. 3)
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In dark conditions, OTC photodegradation is ignored and the Eq. 3 can be simplified to:
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dC SAok3 exp(k3t ) dt V
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Table 1. Parameters used for modeling the OTC release kinetics from PVC microplastics. Parameter
(Eq. 4)
Physical meaning
Small size
t V C
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Release time (h) Solution volume (L) Concentrations of OTCs in PVC-mixed water (µg·L-1) Initial surface area of PVC microplastics (m2) in the A0 suspension, calculated from specific surface area and the corresponding spiked mass of PVC microplastics (m2) Coating density (µg·m-2), calculated from the released OTC S levels in pristine PVC microplastics and A0 k2 First-order kinetics degradation rate constant (h-1) Rate constant describing how fast the OTC-covered surface c area is decreased (h-1) as desorption or release occurs k1 Specific release rate constant (µg·m-2·h-1) a Coating density of DMT on three sized PVC microplastic surfaces.
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2.6. Statistical Analysis
Value Medium size Large size 0.5-56 0.5 Experimental data
10.72±0.28
9.44±0.13
6.47±0.20
4.99±0.20a
3.63±0.05a
0.72±0.02a
To be determined via data fitting To be determined via data fitting k1 S k3
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Each experimental condition was carried out in triplicates at 25 ± 3 °C of room temperature.
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The presented results are the mean values ± standard deviation (SD) from three independent
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experiments. Statistical analysis was performed by the t-test using SPSS Statistics 19.0 software
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(SPSS Inc., USA). The significance was set at p
