Using Ionic Liquid Modified Zeolite as a Permeable Reactive Wall to Limit Arsenic Contamination of a Freshwater Lake—Pilot Tests
by
,
Libing Liao
1,*, 
Zhaohui Li
1,2,*,
Guocheng Lv
1,
Lefu Mei
1,
Haijuan Wang
3,
Shuliu Shi
1,
Yaozu Wei
1,
Xiaoyu Wang
1,
Ping Ning
3 and
Yanke Wei
1 1
Beijing Key Laboratory of Materials Utilization of Nonmetallic Minerals and Solid Wastes, National Laboratory of Mineral Materials, School of Materials Science and Technology, China University of Geosciences, Beijing 100083, China
2
Geosciences Department, University of Wisconsin—Parkside, Kenosha, WI 53141-2000, USA
3
Faculty of Environmental Science and Engineering, Kunming University of Science and Technology, Kunming 650500, China
*
Authors to whom correspondence should be addressed.
Water 2018, 10(4), 448; https://doi.org/10.3390/w10040448
Submission received: 13 March 2018
/
Revised: 2 April 2018
/
Accepted: 4 April 2018
/
Published: 9 April 2018
(This article belongs to the Special Issue Advances in Wastewater Treatment using Zeolite and Anammox)
Abstract
:Arsenic (As) contamination of surface water has long been a threat to human health. Extensive studies were made at the bench-scale for the removal of As from water. Commonly-used materials for the removal of As include Al and Fe hydroxides that will form complexes with As. Recently, modification of Earth materials to reverse their surface charge to positive to reduce the mobility of arsenite and arsenate also attracted great attention. In 2008, a severe As contamination was reported in the lake of Yangzonghai, Yunnan, China. Although the As concentration was maintained below 0.05 mg/L for the lake, after 28 months of restoration, the discharge of mine tailings from a nearby fertilizer plants was still one of the contributors to the As in the lake. In this study, zeolite was modified by ionic liquids and the modified materials were installed as a permeable reactive wall (PRW) to contain the As movement. Preliminary results showed more than an 80% reduction in As after surface water moved through the PWR over the six-month sampling period confirming the effectiveness of ionic liquid-modified Earth materials for environmental application.
1. Introduction
The concept of permeable reactive walls or barriers (PRWs or PRBs) was proposed in the 1990s, mainly for the removal of dissolved contaminants while allowing regular groundwater flow. The initial packing materials for PRWs were granular zero-valent iron (GZVI), due to its exceptional degradation of a variety of inorganic and organic contaminants, such as chlorinated solvents, semivolatiles, arsenic, and chromium. It is often mixed with other porous, yet inactive, ingredients, such as sand. In addition to GZVI, other materials with good hydraulic conductivity, such as surfactant-modified zeolite (SMZ), were also tested for the removal of contaminants of multiple types via sorption or degradation at a pilot scale [1]. As such, numerous studies have been conducted over the last 20 years, mostly in the formulation of the barrier materials for best performance in terms of the rate of removal and types of contaminants to be removed. These studies were mostly at the laboratory-scale, including batch and column tests.
On a separate testing scale, pilot tests of PRWs were also conducted extensively all over the world, mainly for the unconfined aquifers with shallow groundwater table and for dissolved phases of contaminants. A case study was conducted in East Helena, Montana, USA, to treat the groundwater contaminated with arsenic, selenium, lead, cadmium and zinc. After over two years of monitoring, results indicated arsenic concentrations, initially greater than 25 mg/L upgradient of the PRB, were reduced to 2 to < 0.01 mg/L with ~99% removal [2]. A full-scale case study was conducted at a contaminated site in Needham, Massachusetts, USA, with trichloroethene (TCE) as the primary contaminant at a concentration as high as 1100 μg/L. Seven-year data from 2001 to 2007 showed TCE removal rate about 80% with the down-gradient concentration of 5 μg/L [3]. On the opposite side, a pilot scale funnel and gate PRW of 30 ft long by 7 ft deep by 5 ft wide was installed in Colorado, USA, in 2000, to treat the groundwater contaminated with molybdenum (Mb) and uranium (U) with average concentrations of 4.8 and 1 mg/L, respectively [4]. The PWR lost its function to retard the movement of Mo in less than a year. In addition, a reduced hydraulic conductivity due to calcium precipitation resulted in groundwater by passing the PRW [4].
A severe arsenic (As) contamination was reported in the lake of Yangzonghai, Yunnan, China in 2008 [5]. Between December 2008 and September 2009, four rounds of sampling were conducted to investigate the As content and its trends in concentration variation around Yangzonghai Lake in Yunnan Province, Southwestern China [6]. It was found that the arithmetic average of the As contents were 176.9, 147.3, 159.3, and 161.1 μg/L for the lake water and 32.87, 62.41, 62.99, and 46.96 μg/g for the lake sediments, while the higher As concentration in the soil around the lake was 23.33 μg/g [6]. The As content in the lake determined in April 2010 was between 72 and 101 μg/L, increasing as the depth increased, suggesting its sources from surface water input originating from the Phosphor fertilizer plant at the south side [7]. After 28 months of restoration, the As concentration was maintained below 0.05 mg/L, a degree of 80% in comparison to that in October 2008, and the As concentration in the bottom sediments were 21.5–27.0 μg/g [5]. A spray of FeCl3 on the surface of the lake at a rate of 1.6–3.2 mg/L could result in As removal of 95–97% in a pilot test made of 10,000 m3 and 250,000 m3 lake water [8]. In one study, it was concluded that the iron-arsenic precipitates were highly stable in lake water [9]. In another study, the As in sediments was destabilized and the distribution and mobilization of As were affected by the redox conditions and seasonal variations [10]. As the source of the As was believed from the phosphors fertilizer plant about 0.6 km to the southwest of the lake, it is necessary to stop or alleviate the As input from the source to the lake.
The current study is an international collaboration project funded by the Ministry of Science and Technology of China to treat the As-contaminated water and soil collectively in a integrative way with the soil As to be removed by phytoremediation and the As in the surface runoff to the lake to be intercepted with a PRW. As most of the pilot- or full-scale PRW demonstrations were installed underground, primarily for the treatment of groundwater [11] and acid mine drainage [12], this study was the first, to the best of our knowledge, to treat a seasonal surface water for the removal of As at the pilot-scale.
2. Materials and Methods
2.1. Materials
The zeolite was obtained from Weichang, Hebei, China, with components of clinoptilolite and stibnite (see Section 3.1). The zeolite was crushed to particle sizes of 1.0 and 1.5 mm. The ionic liquid (IL) used was 1-hexadecyl-3-methylimidazolium chloride monohydrate (HMCM), purchased from Shanghai Jiecheng Chemical Co. Ltd. (Shanghai, China).
2.2. Lab Zeolite Modification
Modification of zeolite by IL in the laboratory was performed using the following procedures. 20.0 g of zeolite was mixed with 100 mL of IL at concentrations of 200 mmol/L for 12 h. The mixtures were centrifuged for 5 min at a speed of 6000 rpm. After decanting the supernatant, the zeolite was washed with two portions of deionized water before being dried naturally. The product was named as ionic liquid-modified zeolite (ILMZ).
2.3. Batch and Column Tests for As Removal
For batch experiments, 10 mL of As solutions with varying concentrations and 1 g of ILMZ were mixed for 24 h. The column used had a radius of 2.5 cm and a length of 20 cm, resulting in a volume of about 100 cm3. About 80 g of raw zeolite or ILMZ were packed into each column. The packed materials had a porosity of about 0.5, corresponding to a pore volume (PV) of 40 cm3. The initial As (V) concentration was set at about 900 ppb, corresponding to the As concentration in the polluted water. The As-containing water was fed to the column using a peristaltic pump at a flow rate of 0.4 cm3/min.
2.4. Pilot Scale PRW Design
The valley at the narrowest part is 2–3 m wide. An initial design of the PRW was to have the wells collecting water sample at multiple depths, spacing at 0.5 m in elevation and in spacing (Figure 1). Each well is made of 0.25 cm ID and 0.30 cm OD plastic tubes inserted into a 2.5 cm PVC pipe. Each well was installed as a pan lysimeter with the pan holding a volume about 1 L [13].
2.5. Field Scale ILMZ Preparation
At the field scale, a concrete mixer (Figure 2b) was used to mix the zeolite (tan pile in foreground) with the IL (in blue containers of 50 kg containing 70% IL) to achieve a bilayer IL surface coverage. The amount of zeolite to IL used was at a ratio of 1 ton of zeolite to 50 kg of 70% IL with about 0.5 m3 of water added resulting in a solid to liquid ratio of about 2. A total of 20 metric tons were produced over a five-day period. Overall, the amount of IL used was 3% of the zeolite weight.
2.6. Pilot Scale PRW Installation
The PRW was installed in a valley near Yangzonghai Lake, Yunnan Province, which is about 100 km southwest of Kunming (Figure 2a). The valley was dug to 1.0 m below the bottom surface to a width of 4 m and thickness of 2 m. Frameworks were made to fix the location of each monitoring well. Plywood was used to enclose the space for filling the slurry mix of ILMZ. After each batch the ILMZ was transported down to the PRW using a sheet pile to slide the mixture down the river valley. After full installation, the PRW had 20 sampling wells separated by 0.5 m (Figure 3). Each well had 2–3 sampling depth (Figure 1).
2.7. Sampling
The location had dry season and rainy season The PRW was installed in dry season (January 2016) and duplicated samples were taken during the rainy season of 2016 most of the time after rain from the wells that had water using peristaltic pumps. After samples were taken, the wells were pumped dry until refilled with another round of rain. The samples were then transported into the Kunming University of Science and Technology for water chemistry and contaminant analyses.
2.8. Chemical Analyses
For batch and column experiments, the As concentration was analyzed using a Millennium System Excalibur (PS Analytical Ltd., Orpington, UK) with a detection limit of 0.1 µg/L. For the pilot scale demonstration, As was analyzed using an atomic fluorescence method. Fifty milliliters of samples were filleted and then 5 mL of nitric acid was added following by digestion and filtration. The samples were further reduced by adding thiourea+ascorbic acid at a concentration of 60 g/L followed by dilution with 5% HCl before analyses. The instrument used was AF-610D from Beijing Ruili Instrument Co., Beijing, China.
3. Results and Discussion
3.1. The Zeolite Characterization
The XRD analysis showed that the zeolite was made by 65% clinoptilolite and 27% stibnite (Figure 4). The cation exchange capacity (CEC) value of the zeolite was 890 mmol/kg, while the external CEC (ECEC) was 100 mmol/kg. These values provide a foundation for its modification by ionic liquids (IL). Normally, the loading of IL on zeolite should be at 200% of the ECEC value.
3.2. Batch Results on As Removal
The As sorption capacities on ILMZ were 11 and 17 mmol/kg for particles of 0.35–1.0 mm and 1.0–1.41 mm ranges, respectively (Figure 5a). These values are much larger than 6–8 mg/kg sorption of As(III) and As(V) on Fe-exchanged zeolite [14]. In comparison, the ECEC values of the zeolite of these two particle size ranges were 25 and 40 mmol/kg. The As uptake increase with from pH 1 to pH 6, above which the change in As sorption was minute (Figure 5b). The pH of the water in the contaminated area was about 5–6. Thus, it was anticipated that the ILMZ could achieve its best As removal efficiencies. Kinetic study showed that As removal involved in two stages with the first stage almost instantaneous (Figure 5c). At this stage, the amount of As uptake was about 50% of the As uptake at 24 h. More counterion Cl was removed as As sorption on ILMZ (Figure 5d), suggesting that surface anion exchange was responsible for the uptake of As. More Cl desorbed due to initial admicelle formation of IL [15]. Although the stability of IL on zeolite was not evaluated, the long-term stability of HDTMA on zeolite against different pH, ionic strengths, and biological activities was confirmed in a batch study [16].
3.3. Column Results on As Removal
Transports of As through raw and ILMZ columns were demonstrated in Figure 6. The retardation factor, defined as the number of pore volumes (PVs) when the effluent concentration was equal to 50% of the input concentration, was 1 for the raw zeolite, showing zero As retardation. In contrast, the retardation factor was 30 and 57 for ILMZ with particle sizes of 0.35–1.0 and 1.0–1.41 mm ranges (Figure 6). The time for effluent concentration to reach the input concentration was 120 to 250 h, in comparison to 70 to 210 h when bismuth impregnated aluminum oxide was used for As removal [17]. The number of PVs to reach full breakthrough was 32 and 80 in this study, while the PV was 15 and 35 for As transport through columns packed with cross-linked macroporous polymer impregnated with hydrous iron oxide [18]. The total output volume with an effluent As concentration less than 10 ppb was about 450–550 mL. These values correspond to treating 450–550 t of As contaminated water at an initial concentration of 900 ppb per ton of ILMZ.
3.4. Pilot Tests on As Transport through PRW
The special and temporal As concentration profiles in the PRW are illustrated in Figure 7.
At the 0.5 m above the base of the PRW, the As concentration remained constant over the six month period. The highest As concentration was still below 0.05 mg/L. The average As concentration at the upper stream of the PRW was 0.14 mg/L, while the average As concentration after passing through the PRW was 0.004 mg/L, with a removal of 96% in May 2016. Similarly the average As concentration at the upper stream of the PRW was 0.14 mg/L, while the average As concentration after passing through the PRW was 0.01 mg/L, a removal of 92% in June. In July, the average As concentration at the upper stream of the PRW was 0.19 mg/L, while the average As concentration after passing through the PRW was 0.001 mg/L, with a removal of 99%. In August, the average As concentration at the upper stream of the PRW was 0.51 mg/L, while the average As concentration after passing through the PRW was 0.02 mg/L, corresponding to a removal of 96%. Overall, the As removal rate was 96%. As there are no similar PRWs for the removal of As for comparison, data for the removal of other contaminants by PRWs were briefly compared. A pilot scale PRW installed in an industrial facility in New York in 1995 and the data from two years of monitoring revealed that the degradation rated of volatile organic carbon contents were similar to those obtained from laboratory results [19]. Significant removal of heavy metals was observed for a pilot-scale PRW installed in British Columbia, Canada over a 21-month period [20]. Pilot tests using surfactant-modified zeolite as PRW materials also showed great Cr(VI) and perchloroethyene (PCE) removal in 41 days with a retardation factor of 42 and 29 for Cr(VI) and PCE [15]. This study, although preliminary, also provided data for its PWR performance over a six-month period. Thus, results confirmed that PRW technologies not only provide remedial processes for underground water, but are also applicable for the treatment of surface channel water.
4. Conclusions
This study was the first to demonstrate using ionic liquid modified zeolite as a permeable reactive wall (PRW) to intercept and remediate surface water contaminated by arsenic (As) at the pilot-scale. Batch studies revealed an As uptake capacity of about 15 mmol/kg. Column studies showed an As retardation factor of 30 to 50. The preliminary data from the pilot study showed that pilot test results agreed with the prediction made in batch and column tests and demonstrated that the PRW can also achieve remediation goals under above-surface condition to treat seasonal surface water.
Acknowledgments
The funding from Ministry of Science and Technology of China under the grant no. 2014DFA91000 and Fundamental Research Funds for the Central Universities (2652017366) are greatly appreciated.
Author Contributions
L.L. and Z.L. conceived and designed the experiments; Z.L. and Y.W. installed the PRW; G.L. and L.M. participated the experiments; X.W. and S.S. conducted the batch and column experiments. X.W. and Y.W. analyzed the data; P.N. supervised the whole project; S.S., Y.W., and Y.W. processed the field data; Z.L. drafted the manuscript paper. All co-authors read and approved the final~manuscript.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
Schematic illustrate of the monitoring wells installed in the PRW. The numbers in black font on each well show the sampling port elevation with 1 at 0.5 m above the bottom. The numbers in red denote the sample wells in space.
Figure 1.
Schematic illustrate of the monitoring wells installed in the PRW. The numbers in black font on each well show the sampling port elevation with 1 at 0.5 m above the bottom. The numbers in red denote the sample wells in space.
Figure 2.
The location of the pilot test site (a); The ILMZ was produced on site with a concrete mixer (b). The zeolite is in foreground and the IL is in the blue drums. The bags behind the drums are unopened zeolite bags about 100 kg each. The valley where the PRW was installed is in the middle of the picture behind the mixer.
Figure 2.
The location of the pilot test site (a); The ILMZ was produced on site with a concrete mixer (b). The zeolite is in foreground and the IL is in the blue drums. The bags behind the drums are unopened zeolite bags about 100 kg each. The valley where the PRW was installed is in the middle of the picture behind the mixer.
Figure 3.
Photo after the installation of the PRW (a). The front (b); side (c); and top (d) view of the PRW. The top was covered with 0.3 m of concrete to prevent vertical leaching. The left is upstream. Water flows from left to right. The board was later removed. The PWR was in the middle and the front and back portions outside the board were filled with concrete only, thus, no monitoring wells were installed in these portions. Each PVC pipe had 4–5 monitoring wells inside at different depths.
Figure 3.
Photo after the installation of the PRW (a). The front (b); side (c); and top (d) view of the PRW. The top was covered with 0.3 m of concrete to prevent vertical leaching. The left is upstream. Water flows from left to right. The board was later removed. The PWR was in the middle and the front and back portions outside the board were filled with concrete only, thus, no monitoring wells were installed in these portions. Each PVC pipe had 4–5 monitoring wells inside at different depths.
Figure 4.
XRD patterns of the raw zeolite showing nice match (black curve around y = 0) between the observed (pint curve) and fitted (blue circles) data. The vertical lines above the x-axis are for the reflections of the four mentioned minerals.
Figure 4.
XRD patterns of the raw zeolite showing nice match (black curve around y = 0) between the observed (pint curve) and fitted (blue circles) data. The vertical lines above the x-axis are for the reflections of the four mentioned minerals.
Figure 5.
Arsenic sorption isotherm on ILMZ of different particle sizes (a); as a function of initial pH (solid symbols with left Y-axis) and equilibrium solution pH (open symbols with right Y-axis) (b); and affected by contact time (c); and the effect of initial IL loading on As (♦) sorption and counterion Cl (■) desorption (d).
Figure 5.
Arsenic sorption isotherm on ILMZ of different particle sizes (a); as a function of initial pH (solid symbols with left Y-axis) and equilibrium solution pH (open symbols with right Y-axis) (b); and affected by contact time (c); and the effect of initial IL loading on As (♦) sorption and counterion Cl (■) desorption (d).
Figure 6.
Arsenic transport through zeolite and ILMZ of different particle sizes. (a) 0.35–1.0 mm ranges; (b) 1.0–1.41 mm ranges.
Figure 6.
Arsenic transport through zeolite and ILMZ of different particle sizes. (a) 0.35–1.0 mm ranges; (b) 1.0–1.41 mm ranges.
Figure 7.
As concentration across the PRW sampled from 4/20/16 (a); 5/25/16 (b); 6/17/16 (c); 7/11/16 (d); 8/5/16 (e); and 10/19/16 (f). The location of wells was plotted in Figure 3. The flow direction is from the bottom, up. The units of values in the x- and y-axes are meters. The unit for the contour lines is mg/L of As.
Figure 7.
As concentration across the PRW sampled from 4/20/16 (a); 5/25/16 (b); 6/17/16 (c); 7/11/16 (d); 8/5/16 (e); and 10/19/16 (f). The location of wells was plotted in Figure 3. The flow direction is from the bottom, up. The units of values in the x- and y-axes are meters. The unit for the contour lines is mg/L of As.
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MDPI and ACS Style
Liao, L.; Li, Z.; Lv, G.; Mei, L.; Wang, H.; Shi, S.; Wei, Y.; Wang, X.; Ning, P.; Wei, Y. Using Ionic Liquid Modified Zeolite as a Permeable Reactive Wall to Limit Arsenic Contamination of a Freshwater Lake—Pilot Tests. Water 2018, 10, 448. https://doi.org/10.3390/w10040448
AMA Style
Liao L, Li Z, Lv G, Mei L, Wang H, Shi S, Wei Y, Wang X, Ning P, Wei Y. Using Ionic Liquid Modified Zeolite as a Permeable Reactive Wall to Limit Arsenic Contamination of a Freshwater Lake—Pilot Tests. Water. 2018; 10(4):448. https://doi.org/10.3390/w10040448
Chicago/Turabian StyleLiao, Libing, Zhaohui Li, Guocheng Lv, Lefu Mei, Haijuan Wang, Shuliu Shi, Yaozu Wei, Xiaoyu Wang, Ping Ning, and Yanke Wei. 2018. "Using Ionic Liquid Modified Zeolite as a Permeable Reactive Wall to Limit Arsenic Contamination of a Freshwater Lake—Pilot Tests" Water 10, no. 4: 448. https://doi.org/10.3390/w10040448
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