Fs and unintentional persistent organic pollutants

Journal Pre-proof Efficacy of the novel continuous sampling system for PCDD/Fs and unintentional persistent organic pollutants Yen-Chen Hsu, Shu-Hao Chang, Moo Been Chang PII:

S0045-6535(19)32683-9

DOI:

https://doi.org/10.1016/j.chemosphere.2019.125443

Reference:

CHEM 125443

To appear in:

ECSN

Received Date: 4 September 2019 Revised Date:

13 November 2019

Accepted Date: 21 November 2019

Please cite this article as: Hsu, Y.-C., Chang, S.-H., Chang, M.B., Efficacy of the novel continuous sampling system for PCDD/Fs and unintentional persistent organic pollutants, Chemosphere (2019), doi: https://doi.org/10.1016/j.chemosphere.2019.125443. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.

1

Efficacy of the novel continuous sampling system for PCDD/Fs and unintentional

2

persistent organic pollutants

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Yen-Chen Hsu, Shu-Hao Chang, Moo Been Chang

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Graduate Institute of Environmental Engineering, National Central University, Chungli 320, Taiwan

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*Telephone/Fax: +886-3-4226774

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E-mail: [email protected]

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Abstract

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Long-term sampling is essential for monitoring the air pollutants emitted from stack since it can

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monitor the pollutants emission continuously including the stages of start-up, shutdown and normal

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operation. However, commercial continuous sampling equipment such as AMESA faces the

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challenges of high weight and complicated sampling procedures. This study has developed a

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long-term and automatic sampling system (National Central University continuous stack sampling

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system, NCU-CS3), and compared the efficiency with manual sampling train (MST). The results

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indicate that relative standard deviation (RSD) of PCDD/Fs concentrations measured between

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NCU-CS3 and MST is < 20%, demonstrating that the difference between NCU-CS3 and MST in

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measuring PCDD/Fs is insignificant. Besides, the effects of adsorbent temperature, adsorbent amount

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and type of adsorbent on breakthroughs of PAHs and unintentional-persistent organic pollutants

20

(UPOPs) such as polychlorinated dibenzo-p-dioxins and dibenzofurans (PCDD/Fs), polychlorinated

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biphenyls (PCBs), chlorinated phenols (CPs), chlorinated benzenes (CBs) and polychlorinated

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naphthalenes (PCNs) are evaluated. The results indicate that the breakthrough of pollutants increases

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with increasing temperature of XAD-2 and decreases with increasing XAD-2 amount. Moreover,

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XAD-4 is used as alternative adsorbent to test the breakthrough and the results indicate that the

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breakthroughs of UPOPs of XAD-4 as adsorbent are lower than that with XAD-2 due to higher

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specific surface area of XAD-4. Furthermore, the residual of PCDD/Fs with NCU-CS3 as the

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sampling train is relatively low (1.5-3.8%), which meets the regulation of EN 1948-5 (10%).

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Key words: long-term sampling, PAHs, unintentional persist organic pollutants(UPOPs), flue gas

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sampling

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1. Introduction

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During the past a few decades, emissions of polycyclic aromatic hydrocarbons (PAHs) and

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unintentional-persistent organic pollutants (UPOPs) such as polychlorinated dibenzo-p-dioxins and

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dibenzofurans (PCDD/Fs), polychlorinated biphenyls (PCBs), chlorinated phenols (CPs), chlorinated

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benzenes (CBs) and polychlorinated naphthalenes (PCNs) have caused much public concern due to

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their threats to human health (Van Caneghem et al., 2010; Rostami and Juhasz, 2011). Some toxic

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congeners of PCDD/Fs, dl-PCBs, PCNs, CPs and CBs are listed on the Stockholm Convention to

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protect human health and the environment from persistent organic pollutants (POPs), while PAHs are

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carcinogenic to threaten human health. Among these hazardous pollutants, only PCDD/Fs emitted

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from municipal wastes incinerators (MWIs) are rigorously regulated by the developed countries

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worldwide while emissions of PAHs and other UPOPs are not restricted by most countries yet

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(Cheruiyot et al., 2016; UNEP Chemicals, 1999). In order to further protect the human health from

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the hazards caused by these pollutants, investigation on the characteristics of PAHs and UPOPs

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emitted from MWIs is essential.

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Previous studies indicate that concentrations of PAHs and UPOPs emitted from MWIs vary

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significantly with waste composition, combustion condition, operating stage and air pollution control

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devices adopted (Everaert and Baeyens, 2001; Lemieux et al., 2003; Tejima et al., 2007; Chen et al.,

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2008; Aurell and Marklund, 2009; Liu et al., 2014; Li et al., 2017; Wang et al., 2017). Besides, some

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studies indicate that the PCDD/Fs formation is closely related to the precursors such as PAHs, CPs

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and CBs, while PCBs and PCNs have the similar formation pathway as PCDD/Fs (Hajizadeh et al.,

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2011; Li et al., 2016; Cheruiyot et al., 2016). It has been found that PCDD/Fs concentrations

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measured in stack gases during the start-up, shutdowns or operation failures are up to 2 to 3 order

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higher than those measured during normal operation (Tejima et al., 2007; Chen et al., 2008;

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Reinmann et al., 2010). Lothgren and Bavel (2005) indicate that start-up is the main stage of

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increased PCDD/Fs emissions, which has been proved by continuous monitoring covering all periods

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of operation. Besides, it has been found that even with several short-term measurements a year, real

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emission of PCDD/Fs from MWIs still cannot be effectively monitored (Reinmann et al., 2006).

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Arkenbout and Esbensen (2017) indicate that the short-term sampling scheme is seriously flawed on

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PCDD/Fs measurement. In fact, significantly elevated dioxins emissions were measured in flue gas

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during events of unstable combustion conditions by continuous long-term measurements. Besides,

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the dioxin congener patterns from long-term flue gas sampling show similar patterns as the

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congeners found in the samples nearby the MWIs, indicating that elevated dioxins in samples is

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associated with the emissions from the incinerator. Consequently, applying continuous long-term

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sampling to monitor PAHs and UPOPs emitted from MWIs can provide more reliable data compared

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with short-term samplings.

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Three commercial systems, (dioxin emission continuous sampling (DECS), dioxin monitoring

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system (DMS) and adsorption method for sampling of dioxins (AMESA)) have been developed

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respectively based on three long-term sampling methods for sampling PCDD/Fs in flue gas, i.e. (1)

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the filter/condenser method, (2) the dilution method, and (3) the cooled probe method in European

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method (EN1948) (Oleszek-Kudlak et al., 2007). However, the heavyweight of AMESA and DECS

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and memory effect of AMESA have been found in previous studies and may cause danger and

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difficulty during sampling campaign for old stack and overestimating the PCDD/Fs concentration

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owing to memory effect, respectively (Idczak et al., 2003; Lin et al., 2012). Moreover, Lewandowski

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and Gemmill (2006) compare the results of two automatic sampling systems (AMESA and DMS)

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and two manual sampling methods and indicate the no significant difference is found between

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AMESA and DMS. On the other hand, notable difference exists between two manual sampling

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methods owing to human error and complex operating procedures of standard sampling methods (EN

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1948) (Vicaretti et al., 2012). Therefore, developing an automatic long-term sampling system based

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on filter/condenser method not only complies with the regulations promulgated in Taiwan but also

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overcomes the disadvantages of manual sampling”.

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Breakthrough test of the adsorbent applied is essential to determine the sampling efficiency

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during long-term sampling. Effects of adsorbent temperature, adsorbent amount and type of

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adsorbent on breakthrough have been verified in previous sampling campaigns (Wilbring and

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Gerchel, 1997; Mayer et al., 2000; Kahr, 2004; Lee et al., 2004; Reinmann et al., 2008a). Relevant

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studies indicate that the breakthrough of PCDD/Fs would not occur in the AMESA if the adsorbent

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temperature is maintained <50oC (Wilbring and Gerchel, 1997; Mayer et al., 2000; Reinmann et al.,

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2008a). Kahr (2004) indicated that breakthrough would not take place for DMS as long as the

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adsorbent temperature is controlled ≤ 40oC and the breakthrough is < 5% with the adsorbent

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temperature of 60oC. During the period of testing the AMESA system, no PCDD/Fs breakthrough is

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observed during four weeks continuous sampling campaign when 70 g XAD-2 is applied as the

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adsorbent (Wilbring and Gerchel, 1997; Reinmann et al., 2008a, 2008b). On the other hand, the

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specific surface area and pore size of adsorbents may affect the adsorption amount and efficiency of

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pollutants during sampling (Lee et al., 2004).

95 96

In order to comprehensively understand the emission and characteristics of PAHs and UPOPs

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from MWIs, developing a continuous stack sampling system that meets the sampling protocols in

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Taiwan is essential. The objective of this study is to develop a continuous automated sampling

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system which can fulfill the requirements of NIEA A807.75C, EN 1948-1 and EN1948-5 and

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overcome the disadvantages of commercial sampling systems. Besides, the effects of XAD-2 amount,

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temperature of XAD-2 and types of adsorbent (XAD-2 and XAD-4) on the collection efficiencies of

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PAHs and UPOPs emitted from a large-scale MWI located in southern Taiwan are evaluated with the

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sampling system developed. Furthermore, comparison between the automated continuous sampling

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system developed and manual sampling method for short-term sampling of PCDD/Fs is carried out.

105 106

2. Materials and method

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2.1 Basic information of NCU-CS3

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National Central University continuous stack sampling system (NCU-CS3) (as shown in Fig. 1) is

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developed in this study for long-term sampling of PAHs and UPOPs emitted from MWIs. It has the

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advantages of small size (1,240*660*495 mm), high mobility (< 80 kg) and low power consumption

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(<1,300 W) since the gas composition analysis system of NCU-CS3 can be controlled with one

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control unit. Specifically, NCU-CS3 consists of a heated glass sampling tube, filter, oven, two

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adsorbent cartridges and control unit. The temperature of oven and sampling probe is controlled

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within the range of 115-120oC which is lower than that specified NIEA A807.75C (120-134oC) to

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avoid the regeneration and degradation of solid-phase PAHs during the long-term sampling. The

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control unit is comprised of gas composition analysis system, moisture collection system and

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isokinetic suction system that controls the gas flow rate, pressure and temperature of flue gas

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sampled. The flue gas composition analysis system can measure the concentrations of O2, CO2 and

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CO simultaneously. Besides, average percent isokinetic sampling rate is controlled between

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94%-106% (Fig. S1), which meets the requirement of NIEA A807.75C (90-110%). As shown in Fig.

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1, the sampling probe is placed in the center of the stack for continuous sampling. The particulate

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matter (PM) concentration emitted from the MWI investigated is between 3.2-5.7 mg/Nm3 and the

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pressure of the system still maintain < 400 mmHg in the condition of continuous operation for 450 hr.

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Moreover, the leak of flue gas during the sampling period with the NCU-CS3 was less than 5%.

125 126

Fig. 1. Schematic of NCU-CS3 developed for continuous sampling of UPOPs

127 128

2.2 Sample collection by NCU-CS3 and MST

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Overall, 7 samples (No1 to No 7) were collected isokinetically in parallel during the short-term

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sampling period (6-7.8 hr) using manual stack sampling train (MST) and NCU-CS3, respectively, to

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evaluate the performance of NCU-CS3 and make comparison with MST. The manual stack sampling

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method follow Taiwan standard sampling method (NIEA A807.75C) which is modified from the

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USEPA Method 23. In manual stack sampling method, the sampling probe was made from

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borosilicate glass and connected with a filter holder placed in the filter oven. The sampling probe and

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filter oven were kept within a temperature range of 120-134oC. The temperatures at the condenser

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outlet (and inlet to XAD-2 resin) and silica gel trap outlet are maintained at a temperature < 20oC for

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efficient capture of PCDD/Fs and water vapor. Isokinetic sampling must be applied to sample the

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particles correctly. According to the EN1948-5, long-term sampling and manual sampling shall be

139

performed in parallel during a specified time period (at least 40 hr). In this study, long-term sampling

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as well as the manual sampling is performed for 6 hr to 8 hr. Besides, the effects of adsorbent

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temperature, adsorbent amount and types of adsorbent (XAD-2 and XAD-4) on the breakthrough

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were carried out for 10 days. For the test of temperature and adsorbent amount, XAD-2 was used as

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the adsorbent resin. In addition, three parameters were selected as following: amount of the XAD-2

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in 1st adsorption cartridge is 35, 70 or 100 g (amount of second XAD-2 is fixed as 70 g); XAD-2

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temperature is adjusted between 10-50oC and types of adsorbent applied include XAD-2 and XAD-4.

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Breakthrough tests with NCU-CS3 were conducted by installing two adsorption cartridges in series

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and the breakthrough is calculated as the ratios of the TEQ and mass concentration of PAHs or

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UPOPs collected in second adsorbent cartridge to the total TEQ collected by rinse, filter, first and

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second adsorbent cartridges (Eq 1). Furthermore, the residual of PCDD/Fs is calculated as the ratio

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of TEQ in rinse to the total TEQ (Eq 2). The loss rate of PCDD/Fs regulated by Taiwan EPA is

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calculated as the ratio of the TEQ concentration of residual PCDD/Fs to 0.1 ng TEQ/Nm3 (Eq 3)

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(Mehl et al., 2003). The TEQ is calculated for PCDD/Fs to evaluate the extent of breakthrough and

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the breakthroughs of other target pollutants are evaluated based on mass concentration.

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Breakthrough (%) =

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Residual (%) =

           

        

×100%.......................................... (Eq 1)

×100%.................................................................. (Eq 2)

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Loss rate (%) =

 /    ." # /$%&

×100%....................................................................... (Eq 3)

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Total mass✽ stands for the total mass of PAHs or UPOPs collected by rinse, filter, first and second

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adsorbent cartridges.

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2.3 Pretreatment and analysis of PAHs and UPOPs

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All standards are bought from Wellington and Cambridge. For PCDD/Fs analysis, the NIEA

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A807.75C is followed, while WP-CVS standard is used for dl-PCBs analysis. The PCNs standards

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are ECN 5558, ECN 2622, PCN-MXA, PCN-MXC, ECN5102, ECN5520, ECN5217, ECN5260,

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WP-ISS. The chlorobenzene standards are CBS, MCBS, MCBZ-1235, and MCBZ-12345, while the

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chlorophenol standards include CPS, MCP-246, MCP-345, MCP-23456, MPCS. Solid-phase and

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gas-phase pollutants were collected by filter and XAD-2, respectively, using isokinetic sampling

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system with both NCU-CS3 and manual sampling methods. Both filter and XAD-2 adsorbent were

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spiked with isotopically labeled surrogate standards before sampling. The rinse was collected from

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washing the sampling tube with three kinds of solvents in the order of acetone, dichloromethane

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(DCM) and toluene. The filter, XAD-2 and the rinse of sampling tube were pretreated and analyzed

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following Taiwan NIEA A808.75B. The samples were fortified with 13C-labeld of PAHs and UPOPs

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as internal standard before extraction and then extracted by Soxhlet method which can be divided

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into two stages, i.e., DCM/hexane (1:1) used as solvent for the first stage followed by toluene as the

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second stage. The extracts were concentrated individually and then mixed homogenously. After that,

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the extract was separated into two fractions for cleanup. One fraction in clean-up followed NIEA

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A808.75B for PCDD/Fs and PCBs analysis, and the other was eluted in sequence with 50 mL of

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n-hexane (discard) and 50 mL of n-hexane/DCM (5:1, v/v) (collected and concentrated) in the

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column that containing 10 g silica and 10 g alumina for the analysis of PAHs and other UPOPs.

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Finally, recovery standards were individually added into the extracts and analyzed by HRGC/HRMS

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for 17 PCDD/Fs and 12 PCBs and HRGC/MS/MS for 4-8Cl PCN, 24 PAHs, 3-5Cl CPs, and 3-6Cl

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CBs. The recovery efficiency of PCDD/Fs suggurate standards is between 90-110% which fulfill the

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regulation of NIEA A807.75C (70-130%).

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3. Results and discussion

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3.1 Manual sampling train vs automated NCU-CS3

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The PCDD/Fs concentration emitted from the MWI investigated are measured by MST and

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NCU-CS3, respectively, to evaluate the performances of two methods and the results are summarized

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in Table 1. The PCDD/Fs concentrations of No 1 –No 6 are lower than the PCDD/Fs emission

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standard of large-scale MWIs in Taiwan (0.1 ng I-TEQ/Nm3). However, the PCDD/Fs concentrations

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of No 7 measured by MST and NCU-CS3 are 0.264 and 0.225 ng I-TEQ/Nm3, respectively, which are

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over the emission standard of MWIs regulated by Taiwan EPA. It is attributed to the fact that No 7

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sampling was carried out during the shutdown period of MWI and previous studies indicate that

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incomplete combustion would facilitate the formation of PCDD/Fs since the temperature decreases

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and fluctuates greatly during shutdown period (Šyc et al., 2015; Li et al., 2017). Based on the above

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results, long-term sampling is necessary for monitoring the emission of MWIs covering the periods

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of start-up, shutdown and normal operation.

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In addition, the results of the relative standard deviation (RSD) and relative percent difference

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(RPD) between NCU-CS3 and MST are shown in Table 1, and it indicates the RSD of all seven

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samples are below 35%. The EN 1948-5 indicates that the RSD with PCDD/Fs I-TEQ concentration

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around 0.1 ng I-TEQ/Nm3 determined by the long-term sampling should be within 35 % of the value

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determined by the MST measurement to validate the long-term sampling system. If the PCDD/Fs

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concentrations measured by MST are much lower than 0.1 ng I-TEQ/m3, the value of RSD between

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the MST and the long-term sampling system should follow the regulation proposed by the EN

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1948-5. Moreover, Table 1 indicates that RPD of PCDD/Fs concentration between MST and

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NCU-CS3 methods are < 20%, which is lower than the tolerance level of RPD < 30% as set by JIS

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K0311. Horie at al (2007) used RPD to compare the MST and AMESA methods and the results

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indicate that the RPDs of two facilities are in the wide range of 9%-82% due to the uncertainty

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caused by extremely low PCDD/Fs concentrations. Besides, linear regression of the parallel tests

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data is shown in Fig. 2. The correlation coefficient (R2) between MST and NCU-CS3 is 0.91, which is

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in good agreement with the earlier published results of several comparison tests (Idczak et al., 2003;

211

Horie et al., 2007). Based on the results of PCDD/Fs concentrations measured, RSD, RPD and

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correlation coefficient, we conclude that the difference between the MST and NCU-CS3

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measurement is relatively insignificant. Previous study indicates that notable difference exists

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between two manual sampling methods owing to human error and complex operating procedure

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(Vicaretti et al., 2012), for instance, the adjustment procedure of the isokinetic suction rate of MST is

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more complicated if compared with NCU-CS3, which may cause the variation of particulate-phase

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PCDD/Fs concentration measured. The suction rate of MST is supposed to be checked per 10-15 min

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by the operator while the suction rate of NCU-CS3 can be adjusted automatically every 30 second.

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Some studies use commercial AMESA system to solve the shortcomings of MST, however, previous

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study indicates that the memory effect exists with AMESA during the unstable operating condition of

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incinerator due to the deposition residual PCDD/Fs on the cooling sampling probe and the elbow of

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the sampling tube (Reinmann et al., 2008b; Wang and Lin, 2015). Thus, it is suggested that

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automated NCU-CS3 developed in this study is capable to overcome the human errors involved with

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MST and to reduce the time and cost for sampling preparation (Vicaretti et al., 2012). Compared with

225

other commercial continuous sampling systems, NCU-CS3 has the merits of low weight of

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equipment, low energy consumption and good compatibility with the sampling method promulgated

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in Taiwan. Hence, NCU-CS3 is proved as a reliable continuous sampling system for PCDD/Fs

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sampling.

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Table 1 PCDD/Fs concentrations (ng I-TEQ/Nm3) and the differences between NCU-CS3 and MST

235 No

Sampling period

NCU-CS3

MST

RSD

(%)

RPD

(%)

(hr) 1

6

0.054

0.050

5

8

2

6.2

0.028

0.023

14

20

3

6.8

0.023

0.028

14

20

4

7

0.053

0.050

4

6

5

6.4

0.028

0.031

7

10

6

7.3

0.015

0.018

13

18

7

7.8

0.225

0.264

11

16

236

RSD : (standard deviation of PCDD/Fs TEQ concentration between NCU-CS3 and MST divided by

237

the mean of PCDD/Fs TEQ concentration between NCU-CS3 and MST)×100%

238

RPD : (difference of PCDD/Fs TEQ concentration between NCU-CS3 and MST divided by half of

239

the mean of PCDD/Fs TEQ concentration between NCU-CS3 and MST) ×100%

240

241 242

Fig. 2. Linear regression of PCDD/Fs I-TEQ concentrations determined with MST and NCU-CS3 in

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short-term sampling

244 245 246

3.2 Effects of adsorbent temperature, amount of XAD-2 and type of adsorbent on breakthrough test

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Firstly, XAD-2 is chosen as the adsorption resin for testing the effects of adsorbent temperature

248

and the adsorbent amount on PCDD/Fs breakthrough of the NCU-CS3 for the continuous operation

249

of 10 days and the results are presented in Fig. 3. The results indicate that the breakthrough of

250

PCDD/Fs increases with increasing XAD-2 temperature and decreases with increasing XAD-2

251

amount. Overall, the PCDD/Fs breakthroughs are < 2% as the XAD-2 temperature is controlled <

252

20oC and the XAD-2 amount are set at 35, 70 or 100 g. Except for 35 g of XAD-2 amount, the

253

PCDD/Fs breakthrough is < 1% as the XAD-2 temperature is controlled < 20oC. Therefore, 70 g of

254

XAD-2 and 20oC of XAD-2 temperature are optimal for operating the NCU-CS3 for effective capture

255

of PCDD/Fs. Interestingly, the breakthrough of PCDD/Fs congeners decrease with increasing

256

chlorinated level and it is attributed to the fact that low chlorinated PCDD/Fs with higher vapor

257

pressures have higher tendency to penetrate through the first XAD-2 cartridge and be captured by the

258

second XAD-2 cartridge and the trend is consistent with that reported in previous studies (Wu et al.,

259

2014; Wang and Lin, 2015).

260

Breakthroughs of UPOPs and PAHs with different XAD-2 temperatures are also evaluated and

261

the results are shown in Fig. 4. The results indicate that the breakthroughs of UPOPs and PAHs

262

increase with increasing XAD-2 temperature. It's worth noting that the breakthrough of PAHs

263

increases significantly with increasing XAD-2 temperature. It is attributed to the fact that low-ring

264

PAHs with higher vapor pressures are easier to penetrate, leading to higher breakthrough. As shown

265

in Fig. S1, low-molecular-weight PAHs (2 to 3 ring PAHs) such as naphthalene (8.94% - 24.4%),

266

phenantrene (5.33% - 12.98%) and pyrene (5.12% - 9.5%) are of higher breakthroughs in

267

comparison with high-molecular-weight PAHs (other PAHs < 1%) as the XAD-2 temperatures are

268

controlled at 20oC, 30oC and 50oC, respectively. It also suggests that the XAD-2 temperature has

269

more significant effect on the breakthrough of low-molecular-weight PAHs compared with

270

high-molecular-weight PAHs. Additionally, breakthrough of 12 dioxin-like polychlorinated biphenyls

271

(PCBs) is slightly higher than that of 17 PCDD/Fs due to lower boiling points of PCBs (340-375oC)

272

in comparison with PCDD/Fs (438-537oC) (Reinmann et al., 2008a). In addition, the results shown in

273

Fig. S2 also indicate that co-planar PCBs (TeCB-77, TeCB-81, PeCB-126 and HxCB-169) with

274

higher adsorption potential exhibit lower breakthrough (< 4%) in compared with non-planar PCBs (>

275

4.5%), which suggests that the structures of the PAHs and UPOPs also affect the breakthrough

276

(Cortes et al., 1991). Polychlorinated naphthalenes (PCNs) are of lower boiling points (260-440oC)

277

(UNEP, 2017), resulting in higher breakthrough in comparison with PCDD/Fs. Furthermore,

278

breakthroughs of PAHs, CBs and CPs are significantly higher than that of PCDD/Fs, PCBs and

279

PCNs due to lower boiling points of PAHs (217-495oC), CBs (219-322oC) and CPs (253-310oC)

280

(Reinmann et al., 2008a).

281

Fig. 4 also indicates that breakthroughs of PAHs, CPs and CBs are relatively high as XAD-2 is

282

applied as the adsorbent. In order to ensure the trap efficiency and understand the accurate

283

concentrations of PAHs and UPOPs emitted from the stack gas, appropriate operating parameters of

284

NCU-CS3 for effective capture of PAHs, CBs and CPs are needed. Therefore, XAD-4 is used as

285

alternative adsorption resin to test the breakthroughs of CBs, CPs and PAHs. Fig. 5 shows the

286

comparsion of XAD-2 and XAD-4 on breakthroughs of UPOPs and PAHs with the adsorbent

287

temperature of 35oC and 70 g adsorbent in the first cartridge. The results indicate that the

288

breakthroughs of PAHs and UPOPs with XAD-4 as adsorbent are significantly lower than that with

289

XAD-2 as adsorbent, which is consistent with the previous study (Wang and Lin, 2015). Lower

290

breakthrough can be ascribed to higher specific surface area (750 m2/g) and higher pore volume

291

(0.98 mL/g) of XAD-4 compared with XAD-2 (specific surface area = 300 m2/g and pore volume =

292

0.65 mL/g). Previous studies indicated that XAD-4 was superior to XAD-2 and XAD-16 for PAHs

293

and PCDD/Fs sampling due to the dominance of microspore adsorption (Lee et al., 2004; Wang and

294

Lin, 2015). Hence, it suggests that PCDD/Fs and PCBs can be effectively captured by XAD-2 as the

295

temperature and amount are controlled at 20oC and 70 g, respectively, while XAD-4 is more

296

appropriate as adsorbent for capturing CBs, CPs and PAHs in stack gas.

297 298

Fig. 3. Effects of XAD-2 temperature and XAD-2 amount on the breakthrough of PCDD/Fs sampled

299

with NCU-CS3

300 301

Fig. 4. Effects of XAD-2 temperature on breakthroughs of UPOPs and PAHs with 70 g of XAD-2 in

302

NCU-CS3.

303 304

Fig. 5. Effects of XAD-2 and XAD-4 on breakthroughs of UPOPs and PAHs in NCU-CS3 with 70 g

305

adsorbent and adsorbent temperature of 35oC

306 307

3.3 Residual PCDD/Fs on NCU-CS3

308

Residual PCDD/Fs is collected from washing the sampling probe of the NCU-CS3 with acetone,

309

DCM and toluene in sequence after continuous sampling for 10 days in the MWI investigated. Fig. 6

310

shows the distributions of PCDD/Fs among residual, particle phase and gas phase with NCU-CS3 as

311

the sampling system. The result indicates that the distribution of PCDD/Fs in gas phase (93.2%) is

312

significantly higher than those in particle phase (6.8%) and residual (2.8%), which suggests that the

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PCDD/Fs emitted from the MWI investigated mainly exist in gas phase. However, it is found that the

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residual PCDD/Fs measured during the start-up procedure (6.4%) is significantly higher than that

315

measured during normal operation (3%), which is attributed to the fact that the PM concentration of

316

unstable condition (3.5 mg/Nm3) is higher than that of normal operation (< 1 mg/Nm3). Besides, the

317

residual PCDD/Fs is between 1.5-3.8% (with the average value of 2.8%) and the loss rate of

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PCDD/Fs is between 1-6.4%, which is significantly lower than that reported in the relevant studies

319

which applied AMESA (17.2-37.0%) as sampling system and meet the regulation of EN 1948-5

320

(10%) (Wang and Lin, 2015; Mehl et al., 2003). Higher residual PCDD/Fs observed in AMESA

321

could be attributed to the memory effect and it suggests that PCDD/Fs deposited on the cooled

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sampling probe and the sampling elbow cannot be completely cleaned, which causes the bias on the

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PCDD/Fs measurement (Vicaretti et al., 2012). As for NCU-CS3, the sampling probe equipped is

324

heated to avoid the memory effect and decrease the deposition and condensation of PCDD/Fs on the

325

sampling probe during sampling, which is similar to the commercial long-term sampling system such

326

as DMS and DES. On the other hand, due to smaller diameter of the sampling probe in NCU-CS3,

327

the velocity of flue gas would be higher to avoid the deposition of PCDD/Fs on the sampling tube.

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Interestingly, the results shown in Fig. S3 indicate that the residual of highly chlorinated PCDD/Fs is

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higher than that of low chlorinated PCDD/Fs. The main PCDD/Fs congeners in residual are OCDD,

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1,2,3,4,6,7,8-HpCDD, and OCDF and the percentages of OCDD, 1,2,3,4,6,7,8-HpCDD, and OCDF

331

residual in total PCDD/Fs residual are 15.2%, 11.1% and 8.7%, respectively, since highly chlorinated

332

PCDD/Fs with low vapor pressures are more easily condensed and adsorbed on the sampling probe.

333

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Fig. 6. The percentages of PCDD/Fs among residual, particle phase and gas phase, respectively, in

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NCU-CS3 for 10 days’ continuous sampling

336 337 338 339

Conclusions

340

A long-term automatic sampling system (NCU-CS3) is developed for sampling PAHs and

341

UPOPs from MWI based on the filter/condense method which is in compliance with the regulations

342

of Taiwan EPA. Besides, the difference between MST and NCU-CS3 has been evaluated in this study.

343

The results indicate that the RSD and correlation coefficient of PCDD/Fs TEQ concentration

344

between MST and NCU-CS3 are < 35% and 0.9, respectively, which suggests that NCU-CS3 is

345

reliable and can overcome the disadvantages of manual sampling train. Furthermore, the effects of

346

adsorbent temperature, adsorbent amount and types of adsorbent on breakthrough are evaluated for

347

NCU-CS3 and the results indicate that the breakthrough increases with increasing temperature and

348

decreasing adsorbent amount. The XAD-2 temperature and amount should be controlled at 20oC and

349

70 g, respectively, for ensuring effective capture of PCDD/Fs emitted from MWIs. Additionally,

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NCU-CS3 system with XAD-4 as adsorbent can effectively capture UPOPs and PAHs, especially for

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the pollutants of low boiling points owing to higher the specific surface area. Moreover, low residual

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PCDD/Fs with NCU-CS3 has been found in this study and it fulfills the requirement of EN1948-5

353

(10%).

354 355

Acknowledgement

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This study was financially supported by Taiwan Environmental Protection Administration (EPA) and

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Ministry of science and technology (MOST) (Project no. MOST-105-2221-E-008-006-MY3).

358 359

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Highlights 1. A long-term and automatic sampling system (NCU-CS3) has been developed. 2. The difference between NCU-CS3 and MST in measuring PCDD/Fs is insignificant. 3. Effects of adsorbent temperature, amount and types on tests have been elucidated. 4. Low residual PCDD/Fs with NCU-CS3 has been found in this study.

Author Contribution Statement Yen-Chen Hsu：Conceptualization, Methodology, Writing - Original Draft, WritingReviewing and Editing Shu-Hao Chang：Conceptualization, Methodology, Validation Moo Been Chang:：Conceptualization, Supervision, Project administration

Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: