Abstracts
Abstract
Arsenic pollution is one of the global issues which affect the drinking water supply in Burkina Faso, mainly in rural areas. To mitigate this water pollution, ferromagnetic activated carbon (FAC) has been prepared by chemical activation using rice husk and iron chloride solution to be used as an adsorbent of arsenic. Characterization with some analytical techniques revealed this carbon is microporous with a specific surface area of 150 m2∙g-1 and ferromagnetic properties. This work aims to evaluate the equilibrium conditions of As(V) removal and the adsorption capacity of FAC. Batch experiments were undertaken to evaluate the performance of FAC for arsenic removal under various operating conditions and the mechanism of the removal process. Results showed an increase of the removal percentage with the increase of the contact time, indicating a saturation during 60 min. The removal of As(V) is influenced by the increase of the initial arsenic concentration causing an increase of the adsorption capacity of FAC. The increase of pH showed a variation of the removal percentage indicating a maximum removal at pH 7 which corresponds to an adsorption capacity of 153 µg∙g-1. Both monolayer adsorption and ion exchange constitute the mechanism of removal of As(V) using FAC. The kinetics of the process is described by a pseudo-second order model.
Key words:
- arsenic removal,
- chemical activation,
- ferromagnetic activated carbon,
- water
Résumé
La pollution des eaux par l’arsenic est un des problèmes globaux qui entravent l’approvisionnement en eau potable au Burkina Faso, principalement en milieu rural. Pour pallier cette pollution, du charbon actif ferromagnétique a été préparé par activation chimique à partir de balles de riz et de chlorure de fer hexahydraté pour être utilisé comme adsorbant dans le traitement de l’arsenic. La caractérisation de ce charbon par des techniques analytiques a révélé un charbon microporeux avec une surface spécifique de 150 m2∙g-1 et une propriété ferromagnétique. Ce travail a pour but d’évaluer les conditions d’équilibre de l’élimination de l’As(V) et la capacité d’adsorption du charbon actif. Des expériences en mode batch ont été réalisées pour évaluer la performance de ce charbon dans l’élimination de l’arsenic sous différentes conditions ainsi que pour étudier la cinétique du processus. Les résultats ont montré une augmentation de l’élimination de l’As(V) avec le temps de contact et la saturation du charbon a été obtenue au bout de 60 min de contact. L’augmentation de la concentration initiale en As(V) a entrainé une augmentation de la capacité d’adsorption qui est passé de 0,12 à 3,66 µg∙g-1. L’augmentation du pH entre 3 et 11 a révélé une variation du taux d’élimination de l’As(V) avec un maximum à pH = 7 correspondant à une capacité d’adsorption de 153 µg∙g-1. L’adsorption en monocouche, suivie d’un échange anionique, constitue le mécanisme de l’élimination de l’As(V) par le charbon. La cinétique du processus est de pseudo-second ordre.
Mots-clés:
- élimination d’arsenic,
- activation chimique,
- charbon actif ferromagnétique,
- eau
Article body
1. Introduction
Drinking water supply is one of the most important challenges of African countries, mainly in Sub-Sahara Africa. Water resources are facing many challenges including the increasing demand, pollution, scarcity, climate changes, etc. The presence of toxic trace metals in water, including lead, mercury and arsenic, may impact human health if they occur above World Health Organization (WHO) guidelines for drinking water. According to the WHO, 80% of diseases (malaria, onchocerciasis, gastro-enteritis, etc.) affecting the world’s population are transmitted by water (DESJARDINS, 1997). Arsenic contamination in groundwater for drinking purposes has become a worldwide problem and a serious environmental challenge in the world (MEROLA et al., 2015; KNUDSEN et al., 2005; SHANKAR and SHANKER, 2014). The toxicity of arsenic on humans depends on its chemical forms: both inorganic and organic trivalent arsenicals are more potent toxic than pentavalent forms (HUGHES, 2002). Inorganic arsenic is present in natural water in its two predominant oxidation states: As(III) and As(V) with arsenite more mobile and 60 times more toxic than arsenate (MAJI et al., 2007). Out of the trace elements occurring in the groundwaters of northern Burkina Faso, arsenic has the greatest impact on human health. Medical problems such as skin lesions and cancer are widely known to occur as a consequence of chronic arsenic intake in Northern Burkina Faso (SOME et al., 2012). A previous study in Yatenga Province (North Burkina Faso) showed high arsenic concentrations in tube-wells, which are used by 87% of villagers. The first recognized consequences from chronic exposure to arsenic are melanosis, a skin disorder of hyperpigmentation or keratosis where the skin becomes rough and dry with skin papules (SOME et al., 2012). Arsenic pollution in this area was due to arsenopyrite species in the bedrock (SMEDLEY et al., 2007). High arsenic concentrations in groundwaters have caused the closing of some wells in Lilgomde and Tanili villages in Burkina Faso. Arsenic contamination in groundwater has also become a major environmental concern in Vietnam (BERG et al., 2001). The presence of arsenic in groundwaters of Dong Thap Province (Vietnam) with arsenic concentrations ranging from 0.5 to 978 µg∙L-1 caused skin rashes, breathing problems, general tiredness, chronic diarrheas, etc. (MEROLA et al., 2015).
Technologies including precipitation/co-precipitation, ion exchange, membrane filtration, and adsorption have been developed to remove arsenic from drinking water (USEPA, 2001). Previous work showed that granular ferric hydroxide (GFH) could be successfully used as adsorbents in As(V) removal (SANOU et al., 2016a). However, the high cost of GFH limits its use in developing countries such as Burkina Faso. In addition, investigation on natural laterite from Vietnam demonstrated successful removal of arsenic from water (SANOU et al., 2016a). Many studies have been focused on the production of iron-coated materials and their use as adsorbent in arsenic removal (MAHMOOD et al., 2018a; ANSONE et al., 2012; DIN et al., 2017). Among them, limited research has concerned the use of agricultural wastes/by-products greatly available in Sub-Saharan Africa. In this regard, activated carbons are prepared in Burkina Faso from local biomass and lignocellulosic materials for water and wastewater treatment (SANOU et al., 2016b; GUEYE, 2015). Preliminary study using ferromagnetic activated carbon (FAC) as an adsorbent of arsenic in column experiments was promising (SANOU et al., 2017). However, the mechanism of the process and the microstructure of FAC have not been studied. Therefore, this present work aims to investigate the efficiency of FAC in As(V) removal using batch experiments under various conditions. The kinetics of the process will be studied in order to explain the mechanism of As(V) removal. In addition, the global chemical composition of FAC, the microstructure and the surface area will be determined using analytical methods.
2. Material and methods
2.1 Preparation of ferromagnetic activated carbon (FAC)
Rice husk was obtained from rice fields at Koubri Village (12°10'3" N, 1°21'20" W) in Burkina Faso. Ferromagnetic activated carbon was previously prepared through chemical activation (SANOU et al., 2016b). This method is a modification of the one used by THAJEEL et al. (2013).
2.2 Characterization of FAC
Brunauer-Emmett-Teller (BET) experiments were used to determine the surface area of carbon using an analyzer at liquid nitrogen temperature. Elemental composition and microstructure of carbon were analyzed with energy dispersive spectroscopy (EDS) and scanning electron microscopy (SEM), respectively using a JED-2300, 7410F microscope coupled to an EDS detector. Fourier transform-infrared spectra of carbon were recorded to detect the surface functional groups using an infrared spectrophotometer (Tensor 27, Bruker, Germany) operating in the range of 4 000-400 cm-1 and employing a potassium bromide pellet (KBr). X-rays diffraction of FAC was carried out using a diffractometer (PW-1130, Philips) with the monochromatic radiation Kα1 of copper (1.5406 Å).
The index of iodine (I2) characterizing the microporous structure and the index of methylene blue (MB), considered an indicator of the mesopororosity, were previously determined (SANOU et al., 2017).
2.3 Preparation of As(V) solutions
As(V) solutions were prepared by the dilution of a H3AsO4 standard solution (1 000 mg∙L-1) in doubly distilled water. Solutions with concentrations ranging from 200 to 1 000 µg∙L-1 were used in the following experiments. The arsenic (V) standard solution was commercially obtained from chemical stores.
2.4 Arsenic removal experiments
2.4.1 Equilibrium study
Batch experiments were carried out for arsenic removal in aqueous solutions with ferromagnetic activated carbon. Solutions of 25 mL containing a known arsenic concentration were stirred in 50 mL Erlenmeyer flasks at 400 rpm with 0.1 g of carbon and at pH values ranging from 3 to 11 at 26 ± 2°C. The effect of the initial arsenic concentration on the arsenic removal percentage was studied between 200 and 800 µg As∙L-1 using 0.1 g of FAC in 25 mL of solution with pH 7, 60 min of contact and 26 ± 2 °C at 400 rpm.
After filtration of the mixture using a Whatman filter (0.1 mm), the arsenic concentration was analyzed using the method of hydride generation-atomic absorption spectrophotometer (HG-AAS) at a wavelength of 193.7 nm with an electrode discharge lamp (EDL). The spectrometer was calibrated by using As(V) standard solutions with concentrations ranging from 2 to 20 µg∙L-1. The minimum limit of detection was 1 µg∙L-1. Each experiment was carried out three times and the average value was calculated and used in the figures.
2.4.2 Mechanism: kinetics and isotherm studies
The contact time needed for saturation was determined by varying the contact time from 5 to 120 min at 4 000 rpm with 0.1 g of FAC, pH 7, T = 26 ± 2°C and 25 mL of solution containing initially an arsenic concentration of 1 000 µg∙L-1.
The final concentration and its corresponding adsorption capacity were used to apply the kinetic models of pseudo-first order and pseudo-second order. In addition, the model of WEBER and MORRIS (1963) describing the interaparticle diffusion was applied in order to determine the controlling step of the adsorption kinetics.
Experimental data (final concentration and adsorption capacity) obtained from the study of initial arsenic concentration were used to model different isotherms (Langmuir, Freundlich and Dubinin-Radushkevich).
2.4.3 Calculations
The percentage of arsenic removed was calculated as follows:
where C0 and Ce represent initial and final concentrations of arsenic in solution (µg∙L-1), respectively.
The adsorption capacity (Qe) of FAC expressed in µg∙g-1 was obtained from following relation:
where V represents the volume of the solution (L) and m is the weight or mass of adsorbent.
3. Results and discussion
3.1 Physico-chemical characteristics of FAC
Some parameters such as pH at zero point charge (pHZPC), surface area, moisture content and bulk density are listed in table 1. We noticed a high BET surface area of FAC compared to activated carbons prepared from the same rice husk (SANOU et al., 2016b). In addition, the higher value of the iodine index compared to the one for methylene blue indicated a microporous structure of carbon. The presence of iron in this carbon confirms the insertion of ferrous ions during the activation and pyrolysis steps but the low iron content depends on the low concentration of iron solution used for the activation. All these characteristics of FAC were listed from previous work (SANOU et al., 2017).
3.2 Microstructure of FAC
The energy dispersive spectroscopy spectrum is presented in figure 1. Elemental composition (%, wt/wt) of FAC showed 63.1% of C, 23.9% of O, 10.4% of Si, and 2.6% of Fe.
The high carbon content indicates a carbonaceous structure of FAC. Carbon content is lower in FAC compared to AC (SANOU et al., 2016b). The presence of iron in FAC could be due to the insertion of iron ions from the iron chloride solution used for the activation, indicating the possible existence of iron oxides in FAC.
In figure 2, SEM micrographs of FAC are shown with figures 2a and 2b representing the micrographs at 30x and 500x magnifications, respectively. Figure 2a shows a fine structure of FAC with small pore sizes and round particles while figure 2b indicates the narrowed pores. The white spots in figure 2a would be magnetic iron particles incorporated into the FAC during the steps of the activation and the pyrolysis of the rice husk.
Different functional groups at the surface of FAC are identified in the FT-IR spectrum (Figure 3). The band around 3 407.2 cm-1 would be the hydroxyl group of cellulose or hemicellulose. The vibration of the double band around 2 21.83 and 2 853.18 cm-1 corresponds to the vibrations of Ca-O and Mg-O bonds. The double bond C=C of lignin vibrates at 1 597.19 cm-1 (OUEDRAOGO et al., 2015) and the band around 1 480 cm-1 is attributed to the vibration of the Cu-O bond. The band at 1 097.17 cm-1 could be the vibration of the C-O or Si-O bond. The band at 808.83 cm-1 would be the vibration of the Al-O bond and that at 470.38 cm-1 is for the Fe-O bond of the iron oxides (MAITI et al., 2010). The existence of the hydroxyl group, C-O bond and the aromatic C=C double bond suggests the presence of phenols and ether oxides, indicating that the sites active on the surface of FAC are mainly acid sites.
Composition of FAC obtained by XRD analysis is given in table 2 where we note the presence of several oxides at different percentages.
It appears that quartz and calcium oxide are predominant oxides in the FAC with a significant amounts of hematite, tenorite, and alumina. However, the presence of crystalline iron phases such as magnetite (Fe3O4) and hematite (α-Fe2O3) confirmed the insertion of iron ions into the rice husk during impregnation step. Magnetite (Fe3O4) has a ferromagnetic property (MEILLON, 1996; GUEYE, 2015). The different oxides detected by XRD analysis are identifiable with the chemical elements detected using EDS analysis. The magnetic separation which indicates the magnetization content of FAC was determined and calculations revealed a magnetization rate of 3.7% indicating a ferromagnetic property of FAC due to the presence of the magnetite in the composition of the FAC.
3.3 Influence of operating parameters on arsenic removal
3.3.1 Effect of pH
pH is known as an essential factor affecting the adsorption process as it influences the surface charge of the adsorbent (MAHMOOD et al., 2018b). As(V) solutions of pH varying from 3 to 11 were prepared by adjusting with NaOH (0.1 M) and HCl (0.1 M) solutions and the contact time was fixed at 60 min after examination of the preliminary results of the variation of contact time. Figure 4 shows a variation of arsenic removal percentage following different steps: a constant part between pH 3 and 5 followed by an increase between pH 5 and 7 with an optimum at pH 7, indicating a maximum removal of As(V) at pH 7. The maximum removal of As(V) at pH 7 can be explained by the fact that at this pH both the H2AsO4- and HAsO42- forms of As(V) are present in aqueous solutions. In addition, this point (pH 7) is close to the pHZPC of FAC and there is no electrostatic repulsion between arsenates and the quasi-neutral surface of FAC. The maximum arsenic removal at pH 7 is in agreement with previous work using iron impregnated tea as the source of activated carbon (MAHMOOD et al., 2018a). Between pH 7 and 9, there is a clear decrease of arsenic removal from 30.5% to 25%, due to the repulsion between arsenate ions and the negative charge on the FAC surface (pHZPC = 6.72). There is also the competition between arsenate and hydroxyl ions for the same active sites on the adsorbent surface (LIU et al., 2012). No change in As(V) removing was observed after pH 11. The maximum removal at pH 7 corresponds to an adsorption capacity of 153 µg∙g-1 and pH 7 was used in subsequent experiments. According to the literature, the removal of As(V) using activated carbon occurs by anion exchange process because As(V) has a anionic behavior in aqueous solutions between pH 2 and 12 (ANSARI and SADEGH, 2007).
3.3.2 Effect of initial arsenic concentration
The behavior of As(V) removal was tested with As(V) solutions at concentrations ranging from 200 to 1 000 μg∙L-1, according to arsenic concentration from natural groundwater in Burkina Faso and Vietnam (SANOU et al., 2017). From results (Figure 5), we noticed the decrease in removal from 61% to 30% when the initial concentration of arsenic increased. This result would be due to the fast fixation of arsenate ions combined with a limited number of active sites on the surface of FAC. ANSARI and SADEGH (2007) obtained similar results and they concluded that the lowering of arsenic removal at high concentrations is due to the small number of active sites available on the adsorbent surface. However, arsenic removal capacity increases from 61.6 to 153 µg∙g-1 with initial arsenic concentration between 200 and 800 μg∙L-1 and it remained constant after 800 µg∙L-1 with a maximum capacity of 153 μg∙g-1. The increase of adsorption capacity with initial arsenic concentrations would be due to the increase of arsenate ions and their collision with adsorbent surface (MAHMOOD et al., 2018b)
3.4 Mechanism of As(V) removal
3.4.1 Isotherm models
Three models of isotherms were used with experimental data in order to examine the mechanism of the adsorption process. Data obtained from batch experiments were applied to linearized forms of the isotherm models. The distribution of the adsorbate between the adsorbent surface and the solution at a given temperature can be described by a Langmuir isotherm (Equation 3) and a Freundlich isotherm (Equation 4) (LANGMUIR, 1918; FREUNDLICH, 1906).
Figures 6a and 6b represent respectively Langmuir and Freundlich isotherms and the values of the constants are listed in table 3.
Data reported in table 3 showed a high correlation coefficient value (R2) close to 1 with the calculated capacity of adsorption (qm) comparable to experimental value (153 µg∙g-1) for the Langmuir isotherm. So, As(V) removal correlated with the Langmuir isotherm indicating a monolayer process. This finding is in agreement with previous studies on arsenic adsorption (MAHMOOD et al., 2018a; MAHMOOD et al., 2018b).
From the Langmuir constant b, free energy of Gibbs can be expressed by following relation (MOHAN and PITTMAN, 2007):
The calculated value of the Gibbs free energy was 5 kJ∙mol-1, indicating that the process is not spontaneous but energetically stable on the surface of FAC.
The dimensionless equilibrium parameter RL indicates if the process is an adsorption or not (HALL et al., 1966). This parameter was calculated using equation 6:
Values of the dimensionless parameter at equilibrium were ranged between 0 and 1 indicating that As(V) removal was occurred through an adsorption process as indicated in previous work (MAHMOOD et al., 2018a).
It is well known that Langmuir and Freundlich isotherms don’t suggest anything about the physical or chemical nature of adsorption. In order to know the nature of adsorption, experimental data were used with the Dubinin-Radushkevich isotherm (SINGH and PANT, 2004).
The polanyi potential (ε) can be calculated by the following equation 8:
The representation of this isotherm model is given by the figure 7.
The free energy of adsorption (E), defined as the free energy change when one mole of ion is transferred from infinity to the surface of solid in the solution, was calculated as well (MAJI et al., 2008).
The value of adsorption energy was 14.14 kJ∙mol-1 (Table 4); this value between 8 and 16 kJ∙mol-1 indicates an ion exchange process (HAN et al., 2013), presumably an anion exchange between arsenates and hydroxyl ions involving covalent bonds between arsenates and active sites on the surface. This process, which is seen as the beginning of chemisorption, lends to the formation of inner sphere complexes. This result is in agreement with previous works using activated carbon which suggested physico-chemical adsorption (ANSARI and SADEGH, 2007). We can conclude that both adsorption and anion exchange constitute the mechanism of As(V) removal as a monolayer, as indicated in the literature (RAUL et al., 2013; SHAHID et al., 2019).
3.4.2 Kinetic studies
3.4.2.1 Effect of contact time on As(V) removal
The contact time is an important parameter in batch experiments. From figure 8, the percentage of arsenic removal increased from 24.2% to 48% as the contact time increased from 5 to 120 min, following two steps. The first step between 5 and 60 min corresponded to the gradual occupation of different active sites on the FAC. The increasing phase would be the result of the formation of stronger complex or the migration of arsenates onto the surface of the carbon (SU and PULS, 2001). After 60 min (second step), no change in arsenic removal was observed. This can be explained by the saturation of active sites or the limited number of micropores on the surface of FAC. At saturation, the maximum adsorption capacity of FAC was 153 μg∙g-1 of FAC after 60 min of contact. However, the arsenic removal capacity of FAC remains lower compared to GFH (8 500 µg∙g-1) under similar conditions (DRIEHAUS et al., 1998). The two-step process of arsenic sorption onto FAC may be due to the involvement of a fast ion exchange process followed by chemisorption (MAHMOOD et al., 2011).The initial rapid adsorption rate is perhaps the result of the accessibility of arsenate anions in solution to abundant sites on the surface. However, arsenate ions were adsorbed competitively in the following minutes due to the limited availability of surface sites (DIN et al., 2017).
3.4.2.2 Kinetic models
In order to understand the mechanism of As(V) adsorption, the kinetic data were analyzed using kinetic models. There are the pseudo-first order from equation of LAGERGREN and SVENSKA (1898) based on the adsorption capacity (Equation 10) and pseudo-second order from equation of HO and MCKAY (1999) based on the equilibrium between adsorbate and adsorbent (Equation 11).
with equation (10) representing the pseudo-first order model and equation (11) the pseudo-second order model.
The representation of these equations has given the graphs in figure 9 and the constants of the models are listed in table 5.
A higher value of the correlation coefficient (R2) close to 1 was found with the pseudo-second order model compared to the pseudo-first order model. In addition, the theoretical value of the adsorption capacity qtheo (238 µg∙g-1) was comparable (close) to the experimental value qexp (240 µg∙g-1) using the pseudo-second-order model. These results indicate that the removal of As(V) occurred following pseudo-second order kinetics with a kinetic constant of 0.003 g∙µg-1∙min-1. This result is confirmed by literature data on the kinetic studies of arsenic removal (DIN et al., 2017; ANSONE et al., 2012).
It is generally known that the sorption process is a rate-controlled process, in which the slowest step determines the process rate-limiting step. The kinetic data were further analyzed assuming that the mechanism of soil sorption can generally be described by four consecutive rate-controlling steps, which are external mass transfer, film diffusion, intraparticle diffusion, and surface interactions on active sites (HO et al., 2000; OCAMPO-PEREZ et al., 2012). The rate-limiting step of the sorption can be qualitatively determined by analyzing kinetic data using the Weber-Morris model (WEBER and MORRIS, 1963; OFOMAJA, 2010):
where, Ki is the diffusion coefficient (µg∙g-1∙min-0.5) and C is a constant that gives an indication of the thickness of boundary layer. The sorption process is said to be intraparticle diffusion controlled, if the straight line plot passes through the origin, while the boundary layer diffusion (external mass transfer or film diffusion) may take place if it does not pass through the origin (HO et al., 2000). The plot representing this kinetic model is given in the figure 10.
The calculations revealed the correlation coefficient value of 0.75, and the constant Ki of 5.66 µg∙g-1∙min-1. The low value of R2 and the observation that the curve doesn’t pass through the origin indicate that the intraparticle diffusion is not the limiting step of the process and the mechanism of the process is complex. However, the high value of intercept C (182.43) indicates the effect of transboundary layer. We conclude that the process of As(V) adsorption is controlled by film diffusion as described in the literature (HO et al., 2000; MAHMOOD et al., 2018b; DIN et al., 2017).
3.5 Comparison of adsorption capacity
The comparison of the adsorption capacity of FAC with other adsorbents is a challenge because of the differences in experimental conditions, which impact considerably on the adsorption capacities. However, for the sake of comparison, the values of monolayer adsorption capacity (qm) collected from the literature for various adsorbents under the similar conditions and the one for ferromagnetic activated carbon in the present study are listed in table 6.
The comparison of adsorption capacities (Table 6) indicates that the FAC has an adsorption capacity (153 µg∙g-1) greater than that of ferrihydrite and iron oxide coated sand used as adsorbents (THIRUNAVUKKARASU et al., 2003; MOHAN and PITTMAN, 2007). However, this capacity remains lower compare to GFH and iron-coated materials previously studied (DRIEHAUS et al., 1998; TAWABINI et al., 2011; PEHLIVAN et al., 2013). In addition, the adsorption capacity of materials such as laterite soil and ash remains lower than that for the ferromagnetic activated carbon used in the present work (NEMADE et al., 2009, MAITI et al., 2007, MOSTAFAPOUR et al., 2013). This comparison cannot be more exact because of some experimental factors such as pH, nature of water or solution, temperature, adsorbent weight, etc.).
We conclude that, FAC is a promising adsorbent for the removal of As(V) under the prescribed conditions, compared to other adsorbents.
4. Conclusion
Activated carbon (AC) prepared from rice husk and iron chloride solution was effectively a carbonaceous material with an iron content of 2.6% and a magnetization content of 3.7%. X-ray diffraction showed that the magnetite is the oxide responsible of the ferromagnetic property of FAC. Results from batch experiments indicate that this carbon is an effective adsorbent for As(V) removal from water. The variations of pH revealed an optimum removal of As(V) at pH 7 corresponding to an adsorption capacity of 153 µg∙g-1 for 60 min of contact time. The removal percentage decreased with the increase of initial arsenic concentration while the adsorption capacity of FAC from calculations increased from 61.62 to 153 µg∙g-1. The increase of the contact time caused an increase of the removal percentage until the saturation of all active sites on the surface of FAC after 60 min of contact, corresponding to the maximum capacity of 153 µg∙g-1. The study of the isotherm models revealed a process correlated with the Langmuir isotherm, indicating a monolayer adsorption. The value of free energy of adsorption indicated an anion exchange between arsenates and hydroxyl ions. The removal of As(V) using FAC occurred following a mechanism including both adsorption and ion-exchange with pseudo-second order kinetics. Consequently, this material could be used as a fixed bed in column experiments and pilot systems for the removal of arsenic using real groundwaters.
Appendices
Acknowledgements
Authors are thankful to Federal Ministry for Economic Cooperation and Development, Germany (BMZ), German Academic Exchange Service (DAAD), Excellence Center for Development Cooperation, Sustainable Water Management (EXCEED/SWINDON), and Technical University of Braunschweig (TUBS) for their financial and technical supports.
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