Yangzhong Zhang1, Kai Huang1,2. 1. School of Metallurgical and Ecological Engineering, University of Science and Technology Beijing Xueyuan Rd 30, Haidian District 100083 Beijing China khuang@metall.ustb.edu.cn +86-13552537538. 2. Beijing Key Lab of Green Recycling and Extraction of Rare and Precious Metals, University of Science and Technology Beijing Xueyuan Rd 30, Haidian District 100083 Beijing China.
Fluoride is one of the essential trace elements in the human body. Appropriate intake of fluoride can stimulate the vitality of osteoblasts and strengthen teeth and bones.[1-4] However, once the fluorine in the human body exceeds a certain concentration, it will inhibit osteoblasts, causing dental fluorosis and, in severe cases, growth retardation, infertility, and even damage to the kidneys and the nervous system. The fluorine content of safe drinking water in China is not permitted to exceed 1.0 mg L−1, and the World Health Organization (WHO) standard is less than 1.5 mg L−1.[5,6] At present, more than 200 million people around the world are drinking groundwater with a fluoride concentration of more than 1.5 mg L−1; the most serious situation is in India. According to open reports, more than 66 million people in India suffer from fluorosis, including 4 million children under the age of 14.[7-9] Therefore, solving the problem of fluorine pollution in drinking water has become one of the main tasks of researchers worldwide.There are many techniques for removing fluoride from water, such as electrodialysis,[10,11] ion exchange,[12,13] nanofiltration,[14-16] reverse osmosis,[17] precipitation,[18] and adsorption.[19-22] Electrodialysis, ion exchange, nanofiltration and reverse osmosis are all efficient methods for defluoridation; however, they are complicated, costly, and impractical for some less developed and developing countries. The precipitation method usually uses a calcium salt to convert fluoride in water into a calcium fluoride precipitate for removal. This is a simple and low-cost fluorine removal method; however, it is only useful for water containing high concentrations of fluorine. In water with low concentrations of fluorine, it is difficult to decrease the fluoride in water to below 1.5 mg L−1 by this method. In contrast, adsorption for fluorine removal is being extensively studied by many researchers because of its low cost, simple operation, and abundant raw material sources.[23-26] In recent years, various adsorbents have been reported for the removal of fluoride in water, such as activated carbon,[27,28] activated alumina,[29-31] bone charcoal,[32-34] ion exchangers loaded with high-valent metals,[35,36] and biosorbents loaded with rare earth elements.[37] However, these adsorbents may have low selectivity and experience interference from other anions in water, resulting in poor adsorption efficiency. For example, defluoridation using activated aluminum requires frequent elution due to its very small adsorption capacity for fluoride in practical cases; it also inevitably produces soluble aluminum ions in the water, which have been recognized as harmful to human health. Therefore, it is quite necessary to develop new cost-effective adsorbents for defluoridation of drinking water.In this study, a novel fluorine-removing material was designed in which zirconium ions are loaded onto discarded grape pomace, which is abundantly produced in grape juicing and wine factories. Zirconium is a typical rare metal that mostly exists in the tetravalent state in aqueous solutions and has a strong tendency to hydrolyze in water to form hydrate species such as ZrO2+-(OH); due to these properties, it is usually used as the basic functional component for anion exchange. Preliminary experiments showed that the Zr-loaded grape pomace gel had high efficiency and good selectivity for defluoridation. The development of this adsorbent material may provide a valuable reuse for grape waste. In order to compare the effects of the matrix materials on the defluoridation efficiency, a strongly acidic ion exchange resin, D001, with –SO3H functional groups (abbreviated as Zr(iv)-D001 hereafter) and a weakly acidic ion exchange resin, D113, with –COOH functional groups (abbreviated as Zr(iv)-D113 hereafter) were both chosen for loading of ZrO2+ and testing of fluoride removal efficiency.
Materials and methods
Chemicals and instruments
The chemicals used in this study were of analytical grade and did not require further purification. Nitric acid (HNO3), sodium hydroxide (NaOH), sodium fluoride (NaF), sodium nitrate (NaNO3), sodium chloride (NaCl), disodium hydrogen phosphate (Na2HPO4·12H2O), sodium sulfate (Na2SO4) and sodium carbonate (Na2CO3) were purchased from Beijing Chemical Factory. Zirconium oxychloride octahydrate (ZrOCl2·8H2O) was purchased from Tianjin Guangfu Fine Chemical Research Institute. The fluoride concentrations and pH values of the aqueous solutions were measured using a PF-1-C type fluoride ion selective electrode and a pH meter, respectively, which were purchased from Shanghai Yue-Ci Electronic Technology Co., Ltd. The morphologies and elemental compositions of the adsorbents were observed using a scanning electron microscope and energy dispersive spectrometer (ZEISS), and the composition of the functional group of the adsorbent was observed using a Fourier transform infrared spectrometer (IRTracer-100). The fluoride stock solution was prepared by dissolving 2.21 g of NaF in 1000 mL deionized water. In addition, other solutions of fluoride ions with different concentrations were prepared by diluting the stock solution.
Preparation of Zr(iv)-loaded grape pomace
The grape pomace used to prepare the adsorbent in this study was produced at the Xingtai Grape Wine Company, Hebei Province. First, the grape pomace was washed with deionized water several times to remove the contaminants on the surface of the grape pomace; then, by drying the cleaned grape pomace in an oven at 60 °C for 24 hours, the dried grape pomace was obtained and further crushed by a mechanical crusher, passed through a 40 mesh sieve, and collected for zirconium loading. Next, ten grams of dried grape pomace powder was added to 0.1 mol L−1 ZrOCl2·8H2O solution with an initial pH of 1.35. After stirring for 24 hours, the pH of the solution was found to be 1.11. After filtration, the filter cake was washed three times with deionized water to remove unloaded zirconium ions on the surface of the grape pomace, and the zirconium-loaded grape pomace was then dried in an oven at 60 °C. After drying for 24 hours, the prepared adsorbent was collected for defluoridation tests in the following experiments.
Preparation of Zr(iv)-D001 and Zr(iv)-D113
The strongly acidic ion exchange resin D001 and the weakly acidic ion exchange resin D113 used in this study were purchased from Jiangsu Suqing Water Treatment Engineering Group Co., Ltd. First, pretreatment was performed for the D001 and D113 resins to remove various impurities and contaminants in the synthetic processes, and 10 g of each resin after pretreatment was added to a prepared 0.1 mol L−1 ZrOCl2·8H2O solution with an initial pH of 1.35. After stirring for 24 hours, the pH values of the Zr(iv)-D001 and Zr(iv)-D113 solutions shifted to 1.13 and 1.15, respectively. After filtration, the resins were washed several times with deionized water to remove unloaded zirconium ions on the surface of the resins; then, the wet Zr(iv)-D001 and Zr(iv)-D113 were placed in different labeled reagent bottles for use.
Characterization of the adsorbent
Examination of GP, Zr(iv)-GP and Zr(iv)-GP-F− was carried out using a Fourier transform infrared spectrometer (IRTracer-100) to analyze the functional groups. Scanning electron microscopy (SEM) and energy dispersive spectrometry (EDS) were used to observe the surface morphologies and chemical compositions of the adsorbents before and after adsorption of zirconium ions and adsorption of fluoride. The amount of Zr(iv) ions loaded on the GP was quantitatively evaluated by dissolving 20 mg of Zr(iv)-GP in 8 mL of aqua regia. After filtration, the total concentration of zirconium ions loaded on the grape pomace was determined by ICP/AES. The amount of zirconium ions leaking during the adsorption of fluoride by Zr(iv)-GP was also tested by ICP/AES.
Batchwise adsorption tests
Batch adsorption experiments were performed for the three different adsorbents to investigate their adsorption performance for fluoride. Fluorine removal efficiency was investigated by controlling the time, amount of adsorbent, initial pH and initial fluoride concentration. The adsorption ratio and adsorption capacity were calculated by the following two equations:where Ci and Ce are the initial concentration (mg L−1) and equilibrium concentration of fluoride, respectively. W is the dry weight of the adsorbent (mg), and V is the volume of fluoride solution (mL).Kinetic tests were carried out in order to study the equilibration times and the diffusion constants for fluoride adsorption. In each experiment, 120 mg of Zr(iv)-GP adsorbent and 20 mL of fluoride solution (19.91 mg L−1) were mixed together and stirred for a certain time; then, 700 mg wet Zr(iv)-D001 and Zr(iv)-D113 resins, which equated to 120 mg dried adsorbents, were also mixed with 20 mL fluoride solution (19.91 mg L−1) and then stirred for a certain time. The adsorption isotherm of fluoride was investigated by changing the initial concentration of fluoride. The repeated adsorption–desorption of Zr(iv)-GP was carried out using 0.1 mol L−1 NaOH to investigate the reusability of the Zr(iv)-GP adsorbent.
Continuous adsorption and elution tests
The capability of Zr(iv)-GP to remove fluoride from water and the regeneration performance of the adsorbent were evaluated using a continuous fixed bed column with an inner diameter and height of 1.0 cm and 25 cm, respectively. The fluoride in the fixed bed experiment was set initially at 10.03 mg L−1, the initial pH at 3.0, the flow rate at 1.0 mL min−1, and the amount of adsorbent at 500 mg. The column adsorption experiment was carried out until the fluoride concentration of the effluent approached the initial concentration. The effluent fluoride concentration was analyzed by a fluoride ion-selective electrode. When the continuous adsorption experiment was complete, the fixed bed column was washed several times with deionized water and then desorbed using 0.1 mol L−1 NaOH.
Results and discussion
Characterization of Zr(iv)-GP
Analysis of infrared (IR) spectra
In order to investigate the compositions of the adsorbent functional groups, infrared spectroscopy analysis was performed on raw grape pomace (GP), Zr(iv)-GP and fluoride-adsorbed Zr(iv)-GP, respectively. As shown in Fig. 1, the strong peaks observed for the original GP at 3423, 2927, 1739 and 1631 cm−1 are related to the stretching vibrations of –OH, –CH2, –COO and –CO, respectively. The peak value of 1631 cm−1 changed to 1625 cm−1 after loading zirconium ions, which may be due to ion exchange between the hydrogen ions on the grape pomace and the zirconium ions. Therefore, infrared spectroscopy indicates that carbonyl functional groups play a key role in zirconium ion loading. The fixed zirconium ions in the grape pomace form hydrate compounds, which have anion exchange capability with fluoride ions in aqueous solution to remove fluoride from water.
Fig. 1
FTIR spectra of raw grape pomace (GP), zirconium-loaded dried grape pomace (Zr(iv)-GP) and grape pomace with absorbed fluoride (Zr(iv)-GP-F−) in the range from 4000 to 400 cm−1.
Analysis of SEM and EDS
As shown in Fig. 2, the morphologies and elemental compositions of the original grape pomace (GP), zirconium-loaded grape pomace (Zr(iv)-GP) and grape pomace after adsorption of fluoride (Zr(iv)-GP-F−) were analyzed by scanning electron microscopy (SEM) and energy dispersive spectrometry (EDS), respectively. Fig. 2(a) shows a cross-section of the original grape pomace; the surface is porous and has a large surface area, which should provide convenient conditions for the loading of zirconium ions and fluoride ions, and the raw grape pomace is mainly composed of C, Cl and O elements. Fig. 2(b) shows the epidermal morphology after loading zirconium ions. It is apparent from the energy spectrum that a large number of zirconium ions are loaded on the surface of the grape pomace to form the active sites. Fig. 2(c) shows the epidermal morphology after adsorption of fluoride; the energy spectrum shows that fluoride ions were also successfully adsorbed, which can be ascribed to ion exchange.
Fig. 2
SEM/EDS images of raw grape pomace (GP), zirconium-loaded dried grape pomace (Zr(iv)-GP) and grape pomace with adsorbed fluoride (Zr(iv)-GP-F−).
Effects of adsorbent dosage
In order to investigate the effects of the amount of adsorbent on the adsorption efficiency, the amount of Zr(iv)-GP was varied from 30 mg to 480 mg and the wet Zr(iv)-D001 and Zr(iv)-D113 were varied from 175 mg to 2800 mg, corresponding to the same dried mass values of Zr(iv)-GP. The initial concentration of fluoride was 19.91 mg L−1, the volume of the solution was 20 mL, and the initial pH was set at 3. As shown in Fig. 3, adsorption equilibrium could be achieved when 120 mg of Zr(iv)-GP was added; however, for Zr(iv)-D001 and Zr(iv)-D113, reaction equilibrium was attained at 700 mg and 1400 mg, respectively. This indicates that the adsorption efficiency of Zr(iv)-GP for fluoride removal is much higher than those of Zr(iv)-D001 and Zr(iv)-D113.
Fig. 3
Effects of adsorbent dosage on equilibrium time at different S/L ratios of adsorbents (initial fluoride concentration = 19.91 mg L−1, pHi = 3, temperature = 25 °C, solution volume = 20 mL, contact time = 60 min).
Effects of contact time
Experiments to investigate the effects of adsorbent contact time on fluoride adsorption on Zr(iv)-GP, Zr(iv)-D001 and Zr(iv)-D113 were carried out in the time range of 10 min to 300 min. The initial concentration of fluoride was 19.91 mg L−1, the initial pH was set at 3, and the amounts of Zr(iv)-GP, Zr(iv)-D001 and Zr(iv)-D113 were set at 120, 700, and 1400 mg, respectively. As shown in Fig. 4, the amount of fluoride adsorbed at the beginning increased rapidly with time, and all samples reached equilibrium after 1 h of contact. The equilibrium adsorption amounts of Zr(iv)-GP, Zr(iv)-D001 and Zr(iv)-D113 were 3.21, 0.532 and 0.304 mg g−1, respectively; it was obvious that the biosorbent had the advantage of much greater adsorption capacity for fluoride.
Fig. 4
Effects of contact time on fluoride adsorption using Zr(iv)-GP, Zr(iv)-D001 and Zr(iv)-D113 (initial fluoride concentration = 19.91 mg L−1, pHi = 3, temperature = 25 °C, solution volume = 20 mL, weights of adsorbents = 120 mg, 700 mg, 700 mg, respectively).
Effects of pH
The initial pH of the solution plays a crucial role in fluoride adsorption; it may affect the number of chemically active sites by changing the surface charging state under different pH values. In order to determine the optimum pH, the initial pH of the solution was varied between 2 and 9. As shown in Fig. 5, when the pH was set at 3, the adsorption performance of all three adsorbents exhibited the best efficiency, and the highest adsorption efficiency of Zr(iv)-GP reached 96.13%. In the above studies, it could be found that when the initial pH of the solution was greater than 5, the adsorption ratio became poor; this is obviously due to competition of –OH at higher pH and also because the surface negative charges of Zr(iv)-GP at pH values above 5 became fairly strong, which repels the approaching fluoride anions strongly, as demonstrated in Fig. 2 (ESI).†[38,39] In batchwise tests, it was found that when the initial pH was adjusted to 9, Zr(iv)-GP retained a good adsorption effect for fluoride, and the adsorption ratio could reach 87.74%. By monitoring the pH before and after the reaction, it was found that the main reason for the above phenomenon was that Zr(iv)-GP itself can lower the pH of the solution to below 5, thereby avoiding the interference of hydroxyl ions in the adsorption of fluoride ions by the adsorbent. It is an important finding that Zr(iv)-GP can effectively remove fluoride from a fluorine-containing aqueous solution in the case of pH values greater than 5 and without adjusting the pH in advance. Obviously, the protons were released from the Zr(iv)-GP biosorbent. Additionally, the raw grape pomace gel was used to test its adsorption for fluoride; no removal efficiency was confirmed, which verifies that the existence of zirconium in the grape pomace specifically contributed to its removal efficiency for fluoride.
Fig. 5
Effects of pHi on fluoride adsorption using Zr(iv)-GP, Zr(iv)-D001 and Zr(iv)-D113 (initial fluoride concentration = 19.91 mg L−1, temperature = 25 °C, solution volume = 20 mL, contact time = 60 min, weights of adsorbents = 120 mg, 700 mg, 700 mg, respectively).
Adsorption isotherms of fluoride
As shown in Fig. 6(a), the adsorption isotherms of fluoride by the Zr(iv)-GP, Zr(iv)-D001 and Zr(iv)-D113 adsorbents were tested and compared. As shown, when the concentration is low, the rising curve is quite steep. When the concentration is higher, the curve approaches a platform, which is consistent with the typical single-layer adsorption law. The experimental data were modeled using the Langmuir model, and the formula is as follows:[40]where Ce (mg L−1) and qe (mg g−1) in the formula are the adsorption equilibrium concentration and the adsorption amount, respectively. qmax (mg g−1) is the maximum adsorption capacity and b (L mg−1) is the Langmuir constant, which is an adsorption equilibrium constant related to the binding energy associated with the adsorption process. Fig. 6(b) shows the adsorption isotherm fitted according to formula (3). The maximum adsorption capacities and constants b of the three adsorbents can be calculated from the fitted formula, as listed in Table 1. As seen from the table, the maximum adsorption capacity of Zr(iv)-GP is 7.54 mg L−1, which is much larger than those of the other two adsorbents. Also, the correlation coefficients of the three adsorbents are close to 1 for fitting, which further indicates that the adsorption behavior is consistent with the Langmuir model. Table 2 lists the maximum adsorption capacities and optimum pH values of adsorbents tested by other researchers. It can be seen from the table that the maximum adsorption capacity of the adsorbent used in this study is much larger than those of most other adsorbents; also, the adsorbent used in this study is low-cost, safe and non-toxic, and does not cause secondary pollution to the environment, demonstrating good prospective real applications in the defluoridation of groundwater which contains excessive fluoride.
Fig. 6
(a) Adsorption isotherms of fluoride on Zr(iv)-GP, Zr(iv)-D001 and Zr(iv)-D113: (b) corresponding Langmuir plots (initial fluoride concentration = 19.91 mg L−1, temperature = 25 °C, pHi = 3, solution volume = 20 mL, contact time = 60 min, weights of adsorbents = 120 mg, 700 mg, 700 mg, respectively).
Isotherm parameters for fluoride adsorption on various adsorbents from aqueous solution
Adsorbent
Langmuir model parameters
pH
qmax (mg g−1)
b (L mg−1)
R2
Zr(iv)-GP
3.0
7.54
1.121
0.99
Zr(iv)-D001
3.0
4.85
0.020
0.96
Zr(iv)-D113
3.0
1.14
0.013
0.88
Comparison of adsorption capacities for fluoride on different adsorbents
Adsorbent
pH
Temperature (°C)
qmax (mg g−1)
Ref.
Zr(iv)-GP
3
25
7.54
This study
Zr(iv)-D001
3
25
4.85
This study
Zr(iv)-D113
3
25
1.14
This study
La-impregnated chitosan beads
5
30
4.56
41
Protonated chitosan beads
7
30
7.22
42
Modified native cellulose
—
25
8.55
43
200CT-Zr resin
2.4
30
9.50
44
Hydrous MnO2-coated alumina
4–6
25
7.03
45
La-SOJR
4
30
20.14
46
Al–Zr impregnated cellulose
—
—
5.76
47
Activated alumina
—
—
2.40
48
Effects of co-existing ions
There are usually some interfering impurity ions in actual fluorine-containing water. Therefore, this experiment explored the effects of various interfering ions on the selective fluorine removal efficiency of Zr(iv)-GP. As shown in Fig. 7, the effects of some high concentration anions, such as chloride, nitrate, carbonate, phosphate and sulfate, on the selective fluorine removal of Zr(iv)-GP at different pH values were investigated. It can be seen from the figure that 100 mg L−1 of sulfate, nitrate and chloride did not influence the selective defluoridation of Zr(iv)-GP, while high concentrations of carbonates and phosphates had adverse effects on the selective removal of fluoride using Zr(iv)-GP.
Fig. 7
Effects of co-existing interfering ions during the adsorption of fluoride onto Zr(iv)-GP (initial fluoride concentration = 19.91 mg L−1, temperature = 25 °C, solution volume = 20 mL, contact time = 60 min, weight of adsorbents = 120 mg, pHi = 3).
Leakage of loaded Zr(iv) ions from grape pomace
As mentioned, fluoride ions form very stable complexes with high-valent metal ions such as Fe3+, Al3+ and ZrO2+, according to the study of Taishi Kobayashi and Kenso Fujiwara;[49,50] the Zr(iv) loaded in the grape pomace may leak into the water due to possible coordination with fluoride anions in the defluoridation process, especially under acidic conditions. The present study explores the effects of fluoride concentration and pH on the leakage of loaded zirconium ions from the grape pomace. As shown in Fig. 8, at low pH, when the initial fluoride concentration is below 20 mg L−1, the amount of Zr(iv) leakage is negligible for all the investigated pH values. However, as the initial concentration of fluoride increases, the amount of Zr(iv) leakage into the solutions increases. At high pH, even at high concentrations of fluoride ions, the leakage of Zr(iv) is negligible at alkaline pH, indicating that the desorption of the fluoride by 0.1 mol L−1 NaOH does not cause any leakage of the supported metal ions.
Fig. 8
Leakage of loaded zirconium ion from Zr(iv)-GP with varying concentrations of fluoride at different pH values (temperature = 25 °C, solution volume = 20 mL, contact time = 60 min, weight of adsorbent = 120 mg).
Adsorption/desorption studies on Zr(iv)-GP
In order to investigate the reutilization performance of the adsorbent, a series of adsorption–desorption–adsorption experiments were carried out. The initial concentration of fluoride was set at 19.91 mg L−1, and the initial pH of the solution was 3. Previous studies have shown that sodium hydroxide solution can effectively desorb adsorbed fluoride; therefore, the adsorbent was eluted using 0.1 mol L−1 NaOH in the present study. As shown in Fig. 9, after six consecutive cycles of adsorption–desorption, the adsorbent retained very good adsorption efficiency, and the adsorption ratio reached over 80%. The above results show that Zr(iv)-GP can maintain good adsorption capacity even after several repeat uses, which can greatly reduce its cost in practical applications.
Fig. 9
Adsorption/desorption cycle tests of Zr(iv)-GP (initial fluoride concentration = 1.8 mg L−1, initial pHi = 3, temperature = 25 °C, solution volume = 20 mL, contact time = 60 min, weight of adsorbent = 120 mg).
Fluoride adsorption/desorption mechanism
According to a study by Ilce Gabriela Medina-Meza,[51] large numbers of chemical groups such as polyphenols and anthocyanins can be extracted from grape pomace, and it also contains large amounts of pectic acid and other substances. The presence of these substances provides abundant active sites for the loading of zirconium ions via a cation exchange process. As shown in Scheme 1a, the residual carboxyl groups on pectic acid, whose main component is a polysaccharide polymer existing in the form of a free acid, form a stable metal chelate with zirconium ions. During the loading process, all the positive charges of the supported metal zirconium ions are unlikely to be electro-neutralized by the carboxyl groups because the large polymeric chains of pectic acid have large steric hindrance. Therefore, the loaded zirconium has only one or two positive charges, and the other zirconium ions are probably electro-neutralized by various anions, such as hydroxide ions present in water. The hydroxide ions are anion-exchanged with fluoride in the water to remove fluoride ions in the water. Additionally, this adsorption mechanism also can be shown in Scheme 1b; grape pomace contains large amounts of polyphenolic substances, the hydroxyl groups on the polyphenolic substances form stable chelates with the metal zirconium ions, and the metal zirconium ions are also neutralized by various anions, such as hydroxide ions, present in the water. These hydroxide ions undergo ligand exchange with anions during adsorption to remove fluorine from the water.[52,53] The adsorbed fluoride ion can be eluted with NaOH and also by ligand exchange reactions between fluoride ion and hydroxide ion.
Scheme 1
Mechanism of fluoride adsorption and desorption on the Zr(iv)-loaded grape pomace particles.
Column tests
In order to provide guidance for practical applications on a large scale, the present study evaluated the ability of Zr(iv)-GP to remove fluoride in a continuous fixed bed column. A real groundwater sample containing 1.8 mg L−1 fluoride taken from Guanzhuang Village in Haixing County of Hebei Province, China, was used for the continuous column defluoridation test. Firstly, the groundwater was directly percolated through the Zr(iv)-GP packed column without pre-tuning the pH; as shown in Fig. 10, the breakthrough point was about 120 min. The pH of the outlet water was 6.20 in the early run and increased gradually with flowing time, reaching the original pH of the groundwater at 8.18. Obviously, the protons in the Zr(iv)-GP gel leaked into the flowing water, leading to a decrease in the pH of the early inlet water; however, it was consumed quickly and no longer caused a pH increase of the outlet water after a period of time. Taking the defluoridation efficiency into account, the pH of the inlet groundwater was adjusted by acidification in advance. Fig. 10 indicates that the groundwater at pH 3.0 increased the defluoridation capacity to at least 8 times than that at the pH of the original groundwater sample (8.18). Two and three cycles of adsorption/elution operations caused the defluoridation efficiency to decrease gradually; however, at least 80% of the adsorption capacity was retained. Fig. 10 also demonstrates that after elution using 0.1 mol L−1 NaOH solution, the fluoride concentration in the eluent reached 125.3 mg L−1, which is about 70 times higher than the initial fluoride concentration (1.8 mg L−1). The above experiments show that the fixed bed column equipped with Zr(iv)-GP adsorbent has good removal performance for trace fluoride in water. This study provides the possibility of practical application of the adsorbent for the defluoridation of groundwater.
Fig. 10
Breakthrough curve of real groundwater in a fixed bed column with Zr(iv)-GP (initial fluoride concentration = 1.8 mg L−1, temperature = 25 °C, flow rate = 1.0 mL min−1, weight of adsorbent = 500 mg, bed depth = 3.5 cm).
Conclusion
This study reports a new type of fluorine-removing biomaterial which has been experimentally confirmed to provide superior defluoridation of zirconium-loaded grape pomace in comparison with traditional resins. Energy dispersive X-ray (EDS) spectroscopy, Fourier transform infrared (FTIR) spectroscopy and other techniques confirmed that fluoride ions were successfully adsorbed on Zr(iv)-GP. The Langmuir isotherm model well describes the equilibrium data of fluoride adsorption on Zr(iv)-GP. Column adsorption tests verified that pre-adjusting the groundwater pH increased the fluoride removal capacity by about 8 times that of the original groundwater pH of 8.18. After three cycles of adsorption/elution, the defluoridation efficiency decreased slightly, showing that Zr(iv)-GP is an excellent fluorine removal material that may find real application in the practical groundwater purification field.
Fig. 1
Fig. 2
Fig. 3
Fig. 4
Fig. 5
Fig. 6
Fig. 7
Fig. 8
Fig. 9
Scheme 1
Fig. 10