Asian Journal of atmospheric environment
Asian Journal of atmospheric environment Asian Journal of atmospheric environment
Asian Journal of atmospheric environment
  Aims and Scope Type of Manuscripts Best Practices Contact Information  
  Editor-in-Chief Associate Editors Editorial Advisory Board  

Journal Archive

Asian Journal of Atmospheric Environment - Vol. 13 , No. 4

[ Research Article ]
Asian Journal of Atmospheric Environment - Vol. 13, No. 4
Abbreviation: Asian J. Atmos. Environ
ISSN: 1976-6912 (Print) 2287-1160 (Online)
Print publication date 31 Dec 2019
Received 15 Oct 2019 Revised 05 Dec 2019 Accepted 16 Dec 2019
DOI: https://doi.org/10.5572/ajae.2019.13.4.249

Effect of Conventional Water Pretreatment Devices on Polar Compound Analysis
Joo-Yeon Lee ; Trieu-Vuong Dinh ; Dong-June Kim ; In-Young Choi ; Ji-Won Ahn1) ; Shin-Young Park1) ; Yoo-Jin Jung ; Jo-Chun Kim*
Department of Civil and Environmental Engineering, Konkuk University, 120 Neungdong-ro, Gwangjin-Gu, Seoul 05029, Republic of Korea
1)International Climate and Environmental Research Center, Konkuk University, 120 Neungdong-ro, Gwangjin-Gu, Seoul 05029, Republic of Korea

Correspondence to : * Tel: +82-2-450-4009 E-mail: jckim@konkuk.ac.kr


Copyright © 2019 by Asian Journal of Atmospheric Environment
This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Funding Information ▼

Abstract

In general, water vapor in the sample gas can cause adverse effect on analytical instruments. Therefore, the removal of water vapor from the sample gas is a pivotal issue when analyzing polar compounds. The effects of water pretreatment devices on polar compound analysis were investigated in this study. Nafion dryer and Cooler, which are the most widely used water pretreatment device in the world, were compared. Three types of Nafion dryers and two types of Coolers were used. The main target polar compounds were methyl ethyl ketone (MEK), methyl isobutyl ketone (MIBK), isobutyl alcohol (i-BuAl) and butyl acetate (BuAc) which are designated as odorous compounds in Korea. In order to investigate the effect of the water pretreatment device on target compounds, the water vapor removal test and the recovery test were conducted. When the water vapor removal test was performed with 50% and 90% of RH, Nafion dryers (65.4%-96.6%) showed higher water removal efficiencies than those of Coolers (34.2%-67.2%). During a recovery test, Nafion dryers revealed lower recovery rate and lower reproducibility than Coolers. In particular, Nafion dryers showed very low recovery rate and low reproducibility with respect to MEK and i-BuAl which had high water solubility. It was found that Nafion dryers were not suitable for polar compounds of concern. In addition, Coolers had limitation in water vapor removal as well. Therefore, further research on water pretreatment devices that can overcome the problems is necessary.


Keywords: Water pretreatment device, Nafion dryer, Cooler, Water solubility, Polar compound

1. INTRODUCTION

Recently, more systematic regulations for air pollutants have been implemented in the world as interest in air pollution is increasing (Zhang et al., 2016; Han, 2006; Jeon, 2006). Since air pollution policy has been tightened, more effective and accurate measurements are required. As interest in the precision analysis of air pollutants and VOCs increased, researches on factors affecting sampling and analysis such as water vapor, material of sampling container, and adsorbent have been frequently reported (Kistenev et al., 2012; Ras et al., 2009; Palluau et al., 2007; U.S. EPA, 1998; Campbell et al., 1982). Especially, water vapor contained in samples affects not only the analyte but also analytical instruments. Furthermore, deterioration of adsorption capacity, destabilization of baseline in chromatography, and damage to column could be occurred by water vapor (Haberhauer-Troyer et al., 1999). Moreover, it might also clog the transfer line of the instrument (Sundin et al., 1995), interfere with the identification and quantification of analyte, and result in response variability in mass spectrometer (MS) analysis (U.S. EPA, 1998).

The problems related with water vapor could be minimized by removing water vapor using a water pretreatment device which is a preliminary stage of the sampling system or analytical instrument. Therefore, U.S. EPA and Korean Ministry of Environment (MOE) recommended the use of Nafion dryer and Cooler as a water pretreatment device (Perma pure, 2019; MOE et al., 2018; MOE, 2018; NIER, 2007; U.S. EPA, 1999).

A Nafion dryer, which is the most commonly used as a water pretreatment device, is composed of a copolymer of Teflon and sulfonic acid. Thus, it can be used for highly corrosive gases due to its excellent chemical durability (Perma pure, 2019). Water vapor removal of the Nafion dryer is achieved by adsorption and desorption of water vapor by the Nafion membrane (U.S. EPA, 1998; Yang et al., 1996). On the other hand, Cooler used a Peltier to cool down temperature below a dew point to remove continuously water vapor. The water vapor contained in the sample gas would be condensed into liquid water when it passed through a low temperature impinger (Jahnke, 2000).

Accordingly, Nafion dryers and Coolers widely used in the world and removing water vapor in different manners were compared in this study. MEK (methyl ethyl ketone), MIBK (methyl isobutyl ketone), i-BuAl (isobutyl alcohol), and BuAc (butyl acetate) were selected as main target compounds among odorous compounds present in the ambient air. These target compounds have high solubility in water and require to be pretreated before analysis. In order to evaluate the performance of the water pretreatment devices, a water vapor removal test coupled with a recovery rate of the target compounds was carried out.


2. MATERIALS AND METHODS
2. 1 Materials

Ketones, alcohols, and acetates among VOCs are difficult to measure and analyze due to their high solubility in water. The solubility of MEK, MIBK, i-BuAl, and BuAc was 275 g/L, 95 g/L, 19.1 g/L, and 6.8 g/L, respectively (MOE, 2008). Styrene, on the other hand, had solubility in water of 0.3 g/L and was simply used as a comparative compound (MOE, 2008). In this study, a mixed standard gas (5 compounds mixed, Rigas, Korea) containing 10.3 μmol/mol of MEK, 10.4 μmol/mol of i-BuAl, MIBK, BuAc and styrene was used.

2. 2 Water Pretreatment Device

The water pretreatment devices used in this study were Nafion dryer and Cooler which are used widely in the world. A short length (25.4 cm) Nafion dryer of mono tube (N-Mono) (MD-110-12F-4, Perma Pure products, USA), a long length (360 cm) Nafion dryer of mono tube (N-Roll) (SWG-A01-36/KF, Sensep, Japan), and a short length (30 cm) Nafion dryer of poly tube (50 tubes) (N-Poly) (PD-50T-12MPS, Perma Pure products, USA) were used in this study. Cooler-G (TC-Standard 6122, Buhler technologies, Germany) and Cooler-K (Electric cooler SEC-2001B, Saehan hi-tech.,Ltd., Korea) were also employed. The purge gas of Nafion dryers was N2 gas (99.99%, Rigas, Korea), and the Coolers were set at 4°C of the optimal temperature as recommended by manufacturers.

2. 3 Analytical System

This study was carried out based on the measurement method of target compounds (ISO 16000-6, ISO 16017-1, ISO 16017-2, ES 09307.a) (MOE, 2018; U.S. EPA, 2004, 2003, 2000). A thermal desorber (TD) (Unity 2, Markes international, UK) was used for concentrating target compounds. Gas chromatography (GC) (6890, Agilent technologies, USA)/ Mass spectrometer (MS) (5975, Agilent technologies, USA) was used as an analytical instrument. Capillary column DB-624 (60 m×0.320 mm×1.80 μm) which was suitable for VOC measurement was used. The cold trap of TD was U-T9TNX-2S (Markes international, UK), and the adsorption tube for sampling was C1-AXXX-5003 (Markes international, UK). The operating conditions of the analytical instruments are summarized in Table 1.

Table 1. 
Analytical setup of TD and GC/MS .
TD (Unity 2, Markes international, UK) GC (6890, Agilent technologies, USA)
MS (5975, Agilent technologies, USA)
Cold trap Tenax TA Column DB-624 (60 m×0.320 mm×1.80 μm)
Sample tube desorption 300°C (10 min) Initial temp. 40°C
Cold trap low temp. -10°C Initial hold time 5 min
Cold trap high temp. 300°C Temp. programing 10°C/min → 240°C (5 min)
Cold trap hold time 5 min
Carrier gas (He gas) 1.5 mL/min

2. 4 Experimental Method

In order to evaluate the performance of water pretreatment devices, the experimental procedure is depicted in Fig. 1. To investigate the water vapor removal efficiency, the relative humidity (RH) of samples was varied at RH of 50% and 90% for medium and high humidity. In terms of the recovery rate, RHs of 50% and 80% were selected. In this test, a Tedlar bag was used to store a gas sample comprising of humid air and target compounds. The RH value was 80% to prevent the condensation of water in the Tedlar bag. Odor concentrations were selected based on the Korea national emission permission standard.


Fig. 1. 
Experimental scheme for performance evaluation of water pretreatment device.

2. 4. 1 Analysis and Quality Management

Validation of the analytical method was performed through quality assessment and quality control evaluation. According to a test method, calibration curves were prepared to check the linearity. The limit of detection (LOD), limit of quantification (LOQ), and precision were also evaluated.

The calibration curve was prepared in the concentration range of 10-100 ppb according to the test method. In order to prepare five concentration samples (10 ppb, 20 ppb, 40 ppb, 80 ppb and 100 ppb), 10 mL, 20 mL, 40 mL, 80 mL, and 100 mL of the standard gas were injected into a 10 L Tedlar bag (SKC, USA), respectively, which is filled with N2 (99.999%, Rigas, Korea). The sample was introduced into an adsorption tube for 5 minutes at a flow rate of 100 mL/min using a suction pump with a flow meter. Based on the test method, the coefficient of determination (R2) for the linearity of the calibration curve should be at least 0.98.

The LOD was repeated 7 times with samples at a detectable concentration (0.5 ppb). The LOD was calculated as method detection limit (MDL) by multiplying the standard deviation (SD) for each result by 3.14. The LOQ was also calculated by multiplying the SD by 10. Based on the test method, the calculated MDL should be 10 ppb or less for MEK, i-BuAl, MIBK and BuAc, and 1 ppb or less for styrene.

Precision was evaluated by calculating the SD according to the test method. A sample of 80 ppb in the range of the calibration curve was prepared. The SD was calculated by repeating the measurements 3 times. Based on the test method, the calculated precision should be less than 10%.

2. 4. 2 Removal of Water Vapor

To verify the water vapor removal performance of the water pretreatment device, a humidity generator based on bubble method was made and used. The humidity generator consisted of a bubble bottle, mass flow controllers, a mixing chamber, heaters for the bottle and the chamber. The humidity generator was connected directly to the water pretreatment device and generated humid air with 50% and 90% RH at a flow rate of about 2 L/min. Humidity was measured using humidity sensors (Testo 645, Testo, Germany) at the front and rear of water pretreatment device. The flow rate of humid air through the water pretreatment device was set at 100 mL/min, in this study based on a certified test method (MOE, 2018; U.S. EPA, 2004, 2003, 2000). All experiments were repeated three times.

2. 4. 3 Recovery Test

Four samples were prepared by mixing humid air and standard gas in a 10 L Tedlar bag. 20 mL and 100 mL of standard gases were injected into two Tedlar bags, respectively. The rest of volumes were filled with humid air generated at RH of 50% from humidity generator (Sample 1: 50% RH, 20 ppb; Sample 2: 50% RH, 100 ppb). In the same way, 20 mL and 100 mL of standard gases were injected into two Tedlar bags, respectively, and 9,980 mL and 9,900 mL of humid air with 80% RH were filled in the bag (Sample 3: RH of 80%, 20 ppb; Sample 4: RH of 80%, 100 ppb). In a recovery test, Tedlar bag was used to mix humid air and target compounds, so RH was set to 80% to prevent condensing the humid air on the wall of Tedlar bags.

In order to check concentration levels before target compounds passed water pretreatment devices, prepared samples were adsorbed into adsorption trap tubes at a flow rate of 100 mL/min for 5 minutes using a suction pump with a flow meter. In order to check the concentration of compounds recovered after water vapor was removed; the adsorption tube was also connected to the outlet of the device to adsorb samples. The recovery experiment was repeated three times.


3. RESULTS AND DISCUSSION
3. 1 Quality Assurance

To evaluate the analytical method, a calibration curve was prepared as shown in Fig. 2. The correlation coefficients of the calibration curve of MEK, MIBK, i-BuAl, BuAc and styrene were in the range of 0.999 to 0.9999. In addition, MDL of MEK, MIBK, i-BuAl, BuAc and styrene obtained from multiplying the SD by 3.14 was 0.17 ppb, 0.12 ppb, 0.39 ppb, 0.09 ppb and 0.06 ppb, respectively (Lee et al., 2019). On the other hand, the LOQ of MEK, MIBK, i-BuAl, BuAc and styrene obtained from multiplying the SD by 10 was 0.55 ppb, 0.38 ppb, 1.23 ppb, 0.30 ppb, 0.20 ppb, respectively (Lee et al., 2019). Precision was evaluated as a SD by measuring concentred samples three times at 80 ppb, and the precision of MEK, MIBK, i-BuAl, BuAc, and styrene were evaluated as 1.82%, 5.03%, 2.55%, 4.76%, and 9.84%, respectively (Lee et al., 2019).


Fig. 2. 
Calibration curves of target compounds by TD-GC/MS.

3. 2 Removal of Water Vapor

In order to compare the water vapor removal performance of the water pretreatment devices, a water vapor removal test was performed with humid air at 50% and 90% RH.

At 50% RH, the water vapor removal efficiencies of N-Mono, N-Roll, N-Poly, Cooler-G and Cooler-K were 82.3±0.6%, 84.9±0.2%, 92.9±0.2%, 53.9±0.3% and 34.2±0.9%, respectively. Under 90% RH condition, the water vapor removal efficiencies of N-Mono, N-Roll, N-Poly, Cooler-G and Cooler-K were 65.4±2.8%, 92.4±0.2%, 96.6±0.1%, 67.2±0.1% and 62.4±0.1%, respectively. All water pretreatment devices except for N-Mono showed higher water removal efficiencies at 90% RH than at 50%. In addition, it was confirmed that water removal efficiency for the Nafion dryers was higher than that of Coolers except N-Mono with 90% RH. Since N-Mono had the shortest length and the smallest area of membrane, it could not remove well water vapor contained in the sample at high humidity.

Son et al. (2013) reported that water vapor removal efficiencies were 81.3%-94.5% when a Nafion dryer was used to remove water vapor at 50% and 100% RH. In addition, it was confirmed that the water removal efficiency increased in proportion to the increment of RH from 50% to 100%. Haberhauer-Troyer et al. (1999) also found that the water removal efficiency increased (62% to 90%) as RH increased to 16%, 50% and 85% when water vapor was removed by the Nafion dryer.

The water removal effect of the Nafion dryer is strongly influenced by the length and diameter of tubes, the surface area of membrane, gas flow rate and operation temperature (U.S. EPA, 1998; Leckrone et al., 1997). The Nafion dryers used in this study also showed that water removal efficiencies were different depending on the surface area of Nafion membrane. Surface area obtained from the outside diameter and the length of the Nafion membrane of N-Mono, N-Roll, and N-Poly were 21.88 cm2, 33.91 cm2, and 358.57 cm2, respectively (Perma pure, 2019; Sunsep, 2019). As the surface area of Nafion dryer became wider, the water removal efficiency also increased.

On the other hand, it is reported that the water vapor removal effect of a Cooler depended on material, surface area, length of impinger, gas flow rate, and temperature of cooling parts ( Jahnke, 2000). In addition, Lee et al. (2019) also confirmed that difference in water removal efficiency depended on the internal shape of an impinger and the inner part where water vapor is removed. The impinger having a spiral shape on the wall has a larger contact area than the other impinger, showed higher water vapor removal.

3. 3 Recovery Rate of Water Pretreatment Device

Recovery rates of target compounds with respect to different pretreatment devices were illustrated in Fig. 3.


Fig. 3. 
Recovery rates of water pretreatment devices in this study: (a) 50% RH, 20 ppb; (b) 50% RH, 100 ppb; (c) 80% RH, 20 ppb; (d) 80% RH, 100 ppb (adapted from Lee et al., 2019, appl. Sci.).

When the N-Mono was used to remove water vapor, the average recovery rates for each compound were 43.8%, 6.21%, 54.2%, 53.6%, and 99.6% under all RH and initial concentration conditions of MEK, i-BuAl, MIBK, BuAc, and styrene. For the N-Roll, the average recovery rates were 7.50%, 21.4%, 1.47%, 1.50%, and 82.8%, respectively, under all conditions of MEK, i-BuAl, MIBK, BuAc, and styrene. When the N-Poly was used, the average recovery rates were 2.70%, 14.1%, 0.75%, 1.59%, and 70.7% under all conditions of MEK, i-BuAl, MIBK, BuAc, and styrene, respectively.

On the other hand, when the experiment was performed using Cooler-G, the average recovery rates of each compound were 101%, 81%, 96.3%, 94.6%, and 90.9% under all conditions of MEK, i-BuAl, MIBK, BuAc, and styrene. When water vapor was removed using Cooler-K, the average recovery rates for MEK, i-BuAl, MIBK, BuAc, and styrene under all conditions were 100%, 91.7%, 94.4%, 90.8%, and 88.6%, respectively (Lee et al., 2019).

When water vapor was removed by Nafion dryers the lower overall recovery performance of target compounds was observed clearly. In particular, the N-Roll and the N-Poly showed that the recovery of target compounds was significantly lower than that of N-Mono. Since N-Roll and N-Poly had a larger surface area of Nafion membrane than that of N-Mono, it was presumed that polar compounds were simultaneously removed when water vapor was removed by adsorption-desorption reaction on Nafion membrane. Im et al. (2007) confirmed that the recovery rate was less than 20% when Nafion dryer was used for the analysis of four compounds except styrene.

When analyzing some polar compounds with a Nafion dryer as a water pretreatment device, the analyte was simultaneously removed while water vapor was removed (Zielinska et al., 1996; Hsu et al., 1991; McGlenny et al., 1991). Nafion dryers also led to the rearrangement of some monoterpenes and removed important oxygen compounds (Burns et at., 1983). When water vapor was treated with a Nafion dryer in order to analyze benzene or low molecular VOCs, artificial formation and contamination might be occurred (Seo et al., 2011; Son et al., 2009). Zielinska et al. (1996) reported that all polar compounds were lost when a Nafion dryer was used, and that the concentration of total non-methane hydrocarbons were also reduced to 10-20% as the concentration of some paraffins, olefins, and aromatics decreased. In addition, U.S. EPA (1998) reported that a specific polar VOC was lost when using a Nafion dryer, resulting in a 20%-30% reduction in recovery of total non-methane organic compounds. The U.S. EPA (1998, 1999) also reported that careful selection of a water pretreatment device is needed because polar VOCs could be removed by the pretreatment device including the Nafion dryer.

On the other hand, the Coolers showed higher recovery rate than the Nafion dryers. In particular, the Cooler-G showed slightly higher recovery than the Cooler-K for all compounds except i-BuAl. This difference might be occurred by the material of an impinger. Impinger materials for the Cooler-G and the Cooler-K were Teflon and Glass, respectively. According to Deming et al. (2019), the effect of different materials on gaseous compounds was tested using tubes of various materials, and it was confirmed that Teflon material did not affect gaseous compounds rather than glass.

In addition, Lee et al. (2019) reported that i-BuAl had a lower recovery than other compounds due to the high water solubility and low vapor pressure of i-BuAl. MEK which has the highest solubility in water was dissolved rapidly in condensed water in the Cooler's impinger. However, due to its high vapor pressure (78 mmHg, at 20°C), it evaporated quickly to maintain equilibrium. On the other hand, i-BuAl has high solubility in water and dissolves rapidly in condensed water. However, due to its low vapor pressure (9 mmHg, at 20°C), the time to equilibrium is delayed, resulting in low recovery.

For condensation dryers such as Coolers, Dunder et al (1997) warned that the use of condensation dryers could remove compounds that are intended to be analyzed by the interaction of condensed water with water-soluble air pollutants. Kim (2018) confirmed that O3 and SO2 recovered 61.1%-88.0% and 38.6%-80.7% after removing water vapor by using a Cooler. Therefore, if a Nafion dryer and a Cooler are used for the analysis of polar and reactive compounds, it might affect compounds to be analyzed.

The reproducibility of polar compounds concerned after water vapor removal was evaluated as relative standard deviation (RSD).

Nafion dryers showed very unstable reproducibility with respect to MEK and i-BuAl which had high solubility, as presented in Fig. 4. In particular, the N-Roll showed the worst reproducibility with maximum RSD of 117% and 60.3% for i-BuAl and BuAc at all conditions. In addition, the N-Poly showed very unstable reproducibility with maximum RSD of 74% and 100% for MEK and i-BuAl. These results may be caused by adsorption and desorption phenomenon in the Nafion membrane through the process of simultaneous removal of water vapor and polar compounds as mentioned in 3.2 and 3.3.


Fig. 4. 
Reproducibility of target compounds using Nafion dryers: (a) N-mono; (b) N-Roll; (c) N-Poly.

The Coolers showed higher reproducibility than the Nafion dryers as depicted in Fig. 5. However, it was found that there was a lower recovery for i-BuAl. The Cooler-G showed unstable reproducibility with the maximum RSD of 31.2% for i-BuAl. The Cooler-K also revealed the unstable reproducibility of RSD 2.92-8.14% for i-BuAl. This might be related to the internal spiral shape of the impinger and the low vapor pressure of i-BuAl as mentioned in 3.2 and 3.3.


Fig. 5. 
Reproducibility of target compounds using Coolers: (a) Cooler-G; (b) Cooler-K (adapted from Lee et al., 2019, appl. Sci.).

As presented in Fig. 3, Cooler-G showed slightly higher recovery than Cooler-K for all materials except i-BuAl. However, this difference seemed to be little statistically significant. On the other hand, the reproducibility of the Cooler-K was better than that of the Cooler-G as Fig. 5. Consequently, Cooler-K could be more applicable to a real field than Cooler-G as the water pretreatment device for all target compounds concerned in this study.

The water pretreatment devices should be capable of selectively removing only water vapor without interfering with target analytes. The results of this study and other studies suggested that Nafion dryers and Coolers, which are used most in the world, be inadequate as water pretreatment devices for some peculiar compounds. In particular, since analytes often are present in small quantities in the ambient air, the selection of a suitable water pretreatment device for the analytes is very important.


4. CONCLUSIONS

This study compared both Nafion dryers and Coolers in terms of sampling and analysis performance, which have been widely used as water pretreatment devices for polar compounds. The water vapor removal efficiency of Nafion dryers was generally higher than that of Coolers, except for the N-Mono at RH of 90%. Since the surface area of the N-Roll and the N-Poly were wider than that of the N-Mono, their water vapor removal efficiency was somewhat higher. It is suggested that the N-Mono or the Coolers be not suitable for use as water pretreatment devices when the sample humidity is high.

The recovery test revealed that the Nafion dryers had a significantly lower recovery rate than the Coolers. In particular, the N-Roll and the N-Poly were found to remove large amounts of target compounds except for styrene. For a reproducibility evaluation, Nafion dryers showed particularly low reproducibility for MEK and i-BuAl which have high solubility in water. The low recovery and reproducibility of Nafion dryers for target compounds might be due to the surface area of Nafion membrane. The Cooler-G and the Cooler-K also revealed slightly different recovery and reproducibility because the internal spiral shape and material (e.g., Teflon or glass) of the impinger were different.

Although Coolers showed a higher recovery and stable reproducibility than Nafion dryers, their water vapor removal efficiency was lower than that of Nafion dryers. It was also found that the Nafion dryer had very low recovery and reproducibility for the target compounds in this study. It was consequently considered that Nafion dryers and Coolers were inappropriate as a water pretreatment device for analyzing target compounds of concern.

Suitable water pretreatment device according to the sample environment and the characteristics of the analyte is very important for accurate and reliable analysis. Hence, further research is needed for different water pretreatment devices to find out the appropriate devices with reference to various analytes.


Acknowledgments

This research was supported by the R & D Center for Green Patrol Technologies through R &D for Global Top Environmental Technologies funded by Ministry of Environment (MOE), Republic of Korea.


References
1. Burns, W.F., Tingey, D.T., Evans, R.C., Bates, E. H. (1983) Problems with a Nafion® membrane dryer for drying chromatographic samples. Journal of Chromatography A 269, 1-9
2. Campbell, N.T., Beres, G.A., Blasko, T.J., Groth, R.H. (1982) Effect of water and carbon dioxide in chemiluminescent measurement of oxides of nitrogen. Journal of the Air Pollution Control Association 32(5), 533-535
3. Deming, B.L., Pagonis, D., Liu, X., Day, D.A., Talukdar, R., Krechmer, J.E., de Gouw, J.A., Jimenez, J.L., Ziemann, P.J. (2019) Measurements of delays of gas-phase compounds in a wide variety of tubing materials due to gas-wall interactions. Atmospheric Measurement Techniques 12(6), 3453-3461
4. Dunder, T., Leighty, D.A. (1997) Comparison of thermoelectric and permeation dryers for sulfur dioxide removal during sample conditioning of wet gas streams (No. CONF-970677-TRN:IM9925%%292). Air and Waste Management Association, Pittsburgh, PA (United States), https://www.osti.gov/biblio/351130.
5. Haberhauer-Troyer, C., Rosenberg, E., Grasserbauer, M. (1999) Investigation of membrane dryers and evaluation of a new ozone scrubbing material for the sampling of organosulphur compounds in air. Journal of Chromatography A 852(2), 589-595
6. Han, J.S. (2006) Domestic and foreign regulatory trend of odor. Air Cleaning Technology 19(2), 21-41.
7. Hsu, J.P., Miller, G., Moran III, V. (1991) Analytical method for determination of trace organics in gas samples collected by canister. Journal of chromatographic science 29(2), 83-88
8. Im, M.-S.; Ju, D.-W.; Kim, H.-S.; Song, K.-P.; Park, K.-H. (2007) A Study of Analytical Method for 4 Legally designated Compounds [MEK, MIBK, n-Butyl acetate, i-Butyl alcohol] in Ambient Air Using On-line Thermal Desorber with GC/FID. Journal of Korean Society of Odor Research and Engineering 6, 145-153, http://db.koreascholar.com/article.aspx?code=239577.
9. Jahnke, J.A. (2000) Continuous Emission Monitoring, 2nd ed.; John Wiley & Sons: Hoboken, NJ, USA.
10. Jeon, J.M. (2006) Odor compound measurement and analysis method. Air Cleaning Technology 19(2), 42-54.
11. Kim, D.-J. (2018) The Effect of Water Pretreatment Device on Environmental AIR pollutants (O3, SO2, CO) Measurements and Analysis; Konkuk University: Seoul, Korea.
12. Kistenev, Y.V., Kuryak, A.N., Makogon, M.M., Ponomarev, Y.N. (2012) The system for dehumidification of samples in laser gas analysis. Atmospheric and Oceanic Optics 25(1), 92-95
13. Leckrone, K.J., Hayes, J.M. (1997) Efficiency and temperature dependence of water removal by membrane dryers. Analytical chemistry 69(5), 911-918
14. Lee, J.Y., Dinh, T.V., Kim, D.J., Choi, I.Y., Ahn, J.W., Park, S.Y., Jung, Y.J. Kim, J.C. (2019) Comparison of Water Pretreatment Devices for the Measurement of Polar Odorous Compounds. Applied Sciences 9(19), 4045
15. McGlenny, W.A., Pleil, J.D., Evans, G.F., Oliver, K.D., Holdren, M.W., Winberry, W.T. (1991) Canister-based method for monitoring toxic VOCs in ambient air. Journal of the Air & Waste Management Association 41(10), 1308-1318
16. Palluau, F., Mirabel, P., Millet, M. (2007) Influence of relative humidity and ozone on the sampling of volatile organic compounds on Carbotrap/Carbosieve adsorbents. Environmental monitoring and assessment 127(1-3), 177-187
17. Ras, M.R., Borrull, F., Marcé, R.M. (2009) Sampling and preconcentration techniques for determination of volatile organic compounds in air samples. TrAC Trends in Analytical Chemistry 28(3), 347-361
18. Perma Pure. Available online: http://www.permapure.com (accessed on 1 August 2019)
19. Seo, Y.K., Chung, S.H., Baek, S.O. (2011) Current Status and Prospective of Hazardous VOC in Ambient Air. Journal of Korean Society for Atmospheric Environment 27(6), 734-745
20. Son, E.S., Seo, Y.K., Lee, D.H., Lee, M.D., Han, J.S., Baek, S.O. (2009) A study on the performance optimization of a continuous monitoring method for hazardous VOCs in the ambient atmosphere. Journal of Korean Society for Atmospheric Environment 25(6), 523-538.
21. Son, Y.S., Lee, G., Kim, J.C., Han, J.S. (2013) Development of a pretreatment system for the analysis of atmospheric reduced sulfur compounds. Analytical chemistry 85(21), 10134-10141
22. Sundin, N.G., Tyson, J.F., Hanna, C.P., McIntosh, S.A. (1995). The use of Nafion dryer tubes for moisture removal in flow injection chemical vapor generation atomic absorption spectrometry. Spectrochimica Acta Part B: Atomic Spectroscopy 50(4-7), 369-375
23. Sunsep, Available online: http://www.bellexinternational.com/products/sunsep/(accessed on 3 October 2019)
24. The Korea National Institute of Environmental Research. (2007) Method for the Measurement of Odorants; The Korea National Institute of Environmental Research: Incheon, Korea.
25. The Korea Ministry of Environment. (2018) Toluene, Xylene, Methyl ethyl Ketone, Methyl Isobutyl Ketone, Butyl Acetate, Styrene and i-Butyl Alcohol-Cold Trap/Thermal Desorption - GC Method (ES09307.a); The Korea National Institute of Environmental Research: Incheon, Korea.
26. The Korea Ministry of Environment. (2018) VOCs-Cold Trap-GC Method - on-Line Monitoring Method (ES 09906.a); The Korea National Institute of Environmental Research, Incheon, Korea.
27. The Korea Ministry of Environment. (2008) Annual Environmental Report; The Korea Ministry of Environment: Sejong, Korea.
28. The Korea Ministry of Environment, The Korea National Institute of Environmental Research. (2018) Air Pollution Monitoring Network Installation and Operation Guidelines. The Korea Ministry of Environment, Sejong, Korea http://www.me.go.kr/home/web/public_info/read.do;jsessionid=ZoQ68eydUH63yakjSV1mZ90hrC6nKwmuIaIGNXrdI-wh87RtigvMG7pOtmCAYSzFJ.meweb1vhost_servlet_engine1?pagerOffset=0&maxPageItems=10&maxIndexPages=10&searchKey=&searchValue=&menuId=10357&orgCd=&condition.publicInfoMasterId=2&condition.deleteYn=N&publicInfoId=426&menuId=10357.
29. U.S. EPA. (2004) ISO 16000-6. Indoor Air - Part 6: Determination of Volatile Organic Compounds in Indoor and Test Chamber Air by Active Sampling on Tenax TA® Sorbent, Thermal Desorption and Gas Chromatography Using MS/ FID; ISO Copyright Office: Geneva, Switzerland.
30. U.S. EPA. (2003) ISO 16017-2. Indoor, Ambient and Workplace Air - Sampling and Analysis of Volatile Organic Compounds by Sorbent Tube/Thermal Desorption/Capillary Gas Chromatography - Part 2: Diffusive Sampling; ISO Copyright Office: Geneva, Switzerland.
31. U.S. EPA. (2000) ISO 16017-1. Indoor, Ambient and Workplace Air - Sampling and Analysis of Volatile Organic Compounds by Sorbent Tube/Thermal Desorption/Capillary Gas Chromatography - Part 1: Pumped Sampling; ISO Copyright Office: Geneva, Switzerland.
32. U.S. EPA. (1999) Compendium Method TO-14A: Determination Of Volatile Organic Compounds (VOCs). In Ambient Air Using Specially Prepared Canisters With Subsequent Analysis By Gas Chromatography; U.S. EPA: Cincinnati, OH, USA.
33. U.S. EPA. (1999) Compendium Method TO-17: Determination of Volatile Organic Compounds in Ambient Air Using Active Sampling Onto Sorbent Tubes; U.S. EPA: Cincinnati, OH, USA.
34. U.S. EPA. (1998) Technical assistance document for sampling and analysis of ozone precursors. United States Environmental Protection Agency, Research Triangle Park, North Carolina, http://www.epa.gov/ttn/amtic/files/ambient/pams/newtad.pdf.
35. Yang, J., Conver, T.S., Koropchak, J.A., Leighty, D.A. (1996) Use of a multi-tube Nafion® membrane dryer for desolvation with thermospray sample introduction to inductively coupled plasma-atomic emission spectrometry. Spectrochimica Acta Part B: Atomic Spectroscopy 51(12), 1491-1503
36. Zhang, H., Wang, S., Hao, J., Wang, X., Wang, S., Chai, F., Li, M. (2016) Air pollution and control action in Beijing. Journal of Cleaner Production 112, 1519-1527
37. Zielinska, B., Sagebiel, J.C., Harshfield, G., Gertler, A.W., Pierson, W.R. (1996) Volatile organic compounds up to C20 emitted from motor vehicles; measurement methods. Atmospheric Environment 30(12), 2269-2286