Metal-Organic Framework-101 (MIL-101): Synthesis, Kinetics, Thermodynamics, and Equilibrium Isotherms of Remazol Deep Black RGB Adsorption

Thi Thanh Chau, Vo; Thi MinhThanh, Huynh; Dinh Du, Pham; Thanh Tam Toan, Tran; Ngoc Tuyen, Tran; Xuan Mau, Tran; Quang Khieu, Dinh

doi:https://doi.org/10.1155/2018/8616921

Journal of Chemistry

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Research Article | Open Access

Volume 2018 | Article ID 8616921 | https://doi.org/10.1155/2018/8616921

Metal-Organic Framework-101 (MIL-101): Synthesis, Kinetics, Thermodynamics, and Equilibrium Isotherms of Remazol Deep Black RGB Adsorption

Vo Thi Thanh Chau,¹Huynh Thi MinhThanh,²Pham Dinh Du,³Tran Thanh Tam Toan,⁴Tran Ngoc Tuyen,⁴Tran Xuan Mau,⁴and Dinh Quang Khieu⁴

Academic Editor: Hossein Kazemian

Received07 Jan 2018

Revised11 Apr 2018

Accepted14 May 2018

Published24 Jun 2018

Abstract

In the present paper, the synthesis of metal-organic framework-101 (MIL-101) and Remazol Deep Black RGB (RDB) adsorption on MIL-101 were demonstrated. The kinetics of RDB adsorption on MIL-101 was studied using Weber’s intraparticle diffusion model and the pseudo-first- and pseudo-second-order kinetic models. Particularly, the statistical method of piecewise linear regression and multi-nonlinear regression was employed to analyse the adsorption data according to the previously mentioned kinetic models. The results indicated that the adsorption process followed the three-step pseudo-first-order kinetic equation, which was consistent with the results of the intraparticle diffusion model with three linear segments. This model best described the experimental data. In addition, the adsorption isotherm data were studied using five adsorption models, namely, Langmuir, Freundlich, Redlich–Peterson, Toth, and Sips in nonlinear forms, and the Langmuir model is the most appropriate for the experimental data. The values of energies of activation of adsorption were calculated, and they revealed that the adsorption process was of endothermic chemical nature. A statistical comparison using Akaike information criterion to estimate the goodness of fit of the kinetic and isotherm models was presented.

1. Introduction

It is well known that wastewater from textile industries, pulp mills, and dyestuff manufacturing has been a potential threat to environment [1, 2]. Various treatment processes such as physical separation, chemical oxidation, and biological degradation have been widely investigated to remove dyes from wastewaters [3]. Among these processes, adsorption technology is considered as one of the most competitive methods because it does not require high operating temperature and has a simple operation as well as low cost, and several coloring materials can be removed simultaneously [4].

MIL-101 has demonstrated good performance in storage and adsorption of gas such as hydrogen storage [5], adsorption of CO₂ and CH₄ [6], and long-chain alkanes [7]. However, there are very few reports studying the adsorption of dyes from aqueous solutions [8–10]. MOFs in general and MIL-101 in particular exhibit high efficiency for adsorption of dyes from aqueous solutions due to their unique structures such as large surface areas, ordered porosity, and high density of adsorption sites (anion and cation). MIL-101 demonstrates excellent adsorption properties for dyes, such as methyl orange (MO), xylenol orange (XO), and uranine. For expanding applications of MIL-101, studying the adsorption of this material for Remazol Deep Black RGB (denoted as RDB) used widely in dye industry will be a concern of this work.

Azo dyes with an azo group are widely used in many textile industries due to their low cost, high solubility, and stability. These dyes and their intermediate products are toxic, carcinogenic, and mutagenic to aquatic life. Remazol Deep Black RGB is a common diazo reactive dye, widely used in textile industries [11]. It is stable and hard to degrade biologically due to the presence of aromatic rings. Thus, RDB removal from textile wastewater has drawn much attention among researchers. Several techniques including adsorption, electrochemistry, and biosorption for RDB treatment have been reported. Soloman et al. [11] applied the electrochemical treatment to hydrolyze Remazol Black. They demonstrated that the performance of the batch recirculation system was better than other reactor configurations studied in terms of capacity utilization and energy consumption. Brazilian pine-fruit shells (Araucaria angustifolia) in their natural form were used as an adsorbent for the removal of RDB dye from aqueous effluents [12]. A biosorption process to discard azo dyes by fungi (Aspergillus flavus) was investigated in batch reactors [13]. Ninety percent of the dye in a 100 mg/L solution was removed. Recently, Thanh et al. [14] reported that iron doping to ZIF-8 significantly enhances RDB adsorption capacity. Fe–ZIF-8 also exhibits photocatalytic degradation of RDB under visible light [15].

Batch adsorption studies focus on two main trends: (i) designing and optimizing experiments with the evaluation of the influence of the experimental variables—this approach enables to estimate the magnitude of the influence of the factors affecting the process and their interactions [16]—and (ii) kinetics, thermodynamics, and equilibrium isotherm adsorption studies [14, 17]. For the latter, several models are used to study adsorption kinetics and isotherms. The parameters in these models are calculated with linear or nonlinear regression approaches. However, the number of parameters in each mode is different. For example, the Langmuir isotherm model contains two parameters, while the Redlich–Peterson isotherm model has three parameters. It is obvious that the greater the number of model parameters, the lower the relative errors (REs) or the sum of squared errors (SSEs). Therefore, the model compatibility needs to be evaluated including SSEs or REs and the number of model parameters as well as the experimental points. However, in the majority of current publications, the goodness of fit for models is estimated based on only the REs or SSEs. To the best of our knowledge, the research on this issue is limited.

In the present study, MIL-101 was employed as an adsorbent for removing RDB dye. The effects of initial concentration, adsorbent particle size, agitation speed, temperature, and pH on the adsorption behavior of RDB onto MIL-101 were investigated. The adsorption kinetic and isothermal studies and the goodness of fit for models were addressed.

2. Experimental

2.1. Materials

Chromium (III) nitrate nonahydrates (Cr(NO₃)₃·9H₂O, Merck, Germany), terephthalic acid, (C₆H₄(COOH)₂, Merck, Germany) (H₂BDC), and hydrofluoric acid (HF, 40%, Merck, Germany) were utilized in this study. Remazol Deep Black RGB (C₂₆H₂₁N₅Na₄O₁₉S₆), (molecular weight = 991.82) was supplied by Thuy Duong Textile Company, Vietnam. The molecular structure of RDB is shown in Scheme 1.

2.2. Apparatus

The powder X-ray diffraction (XRD) pattern was recorded by means of a D8 Advance (Bruker, Germany) with CuKα radiation (λ = 1.5406 Å). The morphology of the obtained samples was determined using transmission electron microscope (TEM) on JEOL JEM-2100F. The specific surface area of the samples was determined by means of nitrogen adsorption/desorption isotherms using a Micromeritics 2020 volumetric adsorption analyzer system. Visible spectrophotometry was measured by using Lambda 25 Spectrophotometer (PerkinElmer, Singapore) at λ_max of RDB dye (600 nm).

2.3. Preparation of MIL-101

MIL-101 was synthesized from chromium (III) nitrate nonahydrates, H₂BDC, and HF using the hydrothermal method [18]. Three samples of MIL-101 with different molar ratios of HF/H₂BDC = 0.00, 0.25, and 0.75 were prepared. In a typical procedure, a mixture of 10 mmol of H₂BDC, 12.5 mmol of Cr(NO₃)₃·9H₂O, x mmol of HF (x = 0.00, 0.25, and 0.75), and 350 mmol of H₂O was heated in a Teflon-lined stainless steel autoclave at 200°C for 8 h. The resulting green solid was filtered and then washed with ethanol in a Soxhlet apparatus for around 12 h to completely remove the unreacted amount of H₂BDC. The obtained MIL-101 was denoted as MHF0 for the molar ratio of HF/H₂BDC = 0, MHF0.25 for 0.25, and MHF0.75 for 0.75.

2.4. Adsorption Kinetic and Thermodynamic Studies

Kinetic studies were carried out in a 3 L plastic beaker. This beaker was equipped with a stainless steel flat-blade impeller using an electric motor to stir the dye solution and a tap near the bottom to withdraw the liquid at any time. MIL-101 (0.50 g) was mixed thoroughly with 1000 mL of the dye solution in the beaker at room temperature. 10 mL of the mixture was withdrawn periodically, and MIL-101 was removed by using a centrifuge. The final dye concentration was determined using the spectrophotometric method. The adsorption capacity of the adsorbent was calculated according to the following formula:where is the adsorption capacity (mg·g⁻¹) at time, is the initial dye concentration (mg·L⁻¹), is the dye concentration (mg·L⁻¹) at time , is the volume of dye solution (L), and is the mass of the adsorbent (g).

For the adsorption isotherm study, an amount of 30, 40, 50, 60, 70, 80, 90, and 110 mg of MIL-101 was added to 8 stopper 250 mL Erlenmeyer flasks containing 100 mL of 100 mg/L RDB solution. The flasks were then placed into a shaker bath at 28 ± 1°C for 24 hours. Thereafter, the supernatant liquid was separated by centrifugation and the final dye concentration was determined with the method mentioned above.

In order to study formal and diffusion kinetics, Weber’s intraparticle diffusion model and pseudo-first- and pseudo-second-order kinetic models were used. Weber’s intraparticle diffusion model is described as in the following equation [19]:where is intraparticle diffusion rate constant (mg·g⁻¹·min^−0.5) and is the intercept which represents the thickness of the boundary layer.

If intraparticle diffusion is the rate-limiting step, then the plot of q versus t^0.5 will give a straight line with a slope that equals k_i and an intercept equal to zero.

The pseudo-first- and pseudo-second-order kinetic models in the nonlinear form are expressed as follows [20]:where and are the adsorption capacity at time (min) and at equilibrium time, respectively, is the rate constants of the pseudo-first-order model (min⁻¹), and is the rate constant of the pseudo-second-order kinetic model (g·mg⁻¹·min⁻¹).

For the thermodynamic study, the experiments were conducted in the same way as in the adsorption kinetics study. However, the adsorption temperature was fixed at 298, 308, 318, and 328 K. The activation energy, , was determined using the Arrhenius equation [21]:where is the rate constant, is the frequency factor, is the gas constant (8.314J mol⁻¹·K⁻¹), and is the absolute temperature in Kelvin. Taking the natural logarithm of both sides of (4), one obtains

By linearly plotting versus 1/T, one could obtain from the slope ().

In order to evaluate whether the adsorption process is spontaneous, the adsorption thermodynamic parameters are needed. The standard Gibbs free energy of adsorption () is given by the following expression:where , , and are the change of standard Gibbs energy, enthalpy, and entropy, respectively.

is given by the van’t Hoff equation:where is the distribution coefficient of the solute ions and equal to [22, 23] and the others are described earlier.

By replacing (6) to (7), one obtains

The value of and is calculated from the slope and intercept of the linear plot of ln versus .

2.5. Adsorption Isotherm Study

Experimental data were analysed according to five isotherm models by Langmuir, Freundlich, Redlich–Peterson, Sips, and Toth.

Langmuir isotherm: Langmuir model is valid for monolayer sorption onto the surface. It could be expressed as follows [24]:where is the maximum monolayer capacity amount (mg·g⁻¹), is the equilibrium constant, is the equilibrium adsorption capacity (mg·g⁻¹), and is the equilibrium concentration of adsorbate (mg·L⁻¹).

Freundlich isotherm: The Freundlich equation is an empirical relation based on the sorption onto a heterogeneous surface. It is commonly represented as [25]where ((mg·g⁻¹)·(mg·L⁻¹)ⁿ) and n are the Freundlich parameters related to adsorption capacity and adsorption intensity, respectively.

The maximum capacity, (mg·g⁻¹), can be calculated from the following equation [26]:where is the initial concentration.

Redlich–Peterson isotherm: Redlich–Peterson isotherm [27] contains three parameters and involves the features of both Langmuir and Freundlich isotherms. It can be described as follows:where (L·g⁻¹) and (L·mg⁻¹) are the Redlich–Peterson isotherm constants and is the exponent which lies between 0 and 1.

When approaches 1, (12) becomes the Langmuir equation. Then, the maximum adsorption capacity, (mg·g⁻¹), can be determined by the following equation:

Sips isotherm: Sips isotherm is a combination of the Langmuir and Freundlich isotherms and expected to describe heterogeneous surfaces much better [24]. The model can be written as [28]where and are the Sips constants related to the energy of adsorption. The maximum monolayer adsorption capacity could is given by .

Toth isotherm: Toth isotherm is the Langmuir-based isotherm and considers a continuous distribution of site affinities. It is expressed as [29]where is the Toth model constant and is the Toth model exponent (). It is obvious that, for , this isotherm reduces to the Langmuir equation.

2.6. Piecewise Linear Regression and Model Comparison

The application of Weber’s model often suffers from uncertainties caused by the multilinear nature of its plots. Malash and El-Khaiary [30] proposed the piecewise linear regression for the analysis of multilinearity in intraparticle diffusion and film diffusion. In this method, the experimental data could be fixed for one-, two-, three-, or four-linear-segment lines: one-linear-segment line: Y = B + A · X (two parameters), two-linear-segment line: Y = B + A · X + C · (X − D)·SIGN (X − D) (four parameters), three-linear-segment line: Y = B + A · X + C · (X − D)·SIGN (X − D) + E · (X − F) · SIGN (X − F) (six parameters), four-linear-segment line: Y = B + A · X + C · (X − D)·SIGN (X − D) + E · (X − F) · SIGN (X − F) + G · (X − H)·SIGN (X − H) (eight parameters),where the values of A, B, C, D, E, F, G, and H are estimated by nonlinear regression. D, F, and H, called breakpoints, are the boundaries between the segments. The Microsoft Excel “SIGN” function is defined as follows:

The example for the three-linear-segment equation is expressed as follows:

Then, the linear equation of the first segment is y = a₁ · x + b₁, where b₁ = B − C − E and a₁ = A + C · D + E · F. The linear equation of the second segment is y = b₂ · x + a₂, where b₂ = B + C – E and a₂ = A + C · D + E · F. The linear equation of the third segment is y = b₃ · x + a₃, where b₃ = B + C + E and a₃ = A − C · D − E · F.

The model’s parameters are determined using the least squares method. This is calculated by minimizing the sum of squared errors, SSE_S, by numerical optimization techniques using the Solver function in Microsoft Excel. The function for minimization iswhere is experimental datum and is the value estimated from the model.

The determination coefficient, , is obtained by the following expression:where is the total sum of squares equal to ( is the mean value of ).

We know that increasing the number of linear segments increases the number of regression parameters that almost universally led to the decrease of SSEs or the increase of . Therefore, the model compatibility cannot be based only on SSE or but must also include the number of regression parameters as well as the experimental points. Akaike’s information criterion (AIC) is one of the well-known statistical methods used in this case.where is the parameter of the model. The other parameters are described above.

The is applied as is small compared with . is only computed as is at least two units greater than . The value of could be positive or negative, and the lower the value, the better it is. Another way of comparing is using the evidence ratio (ER) which is expressed as follows [17]:where Δ is the absolute value of the difference between and scores. ER means that the model with lower is 1/e^−0.5Δ times more likely to be correct than the alternative model.

In the present study, the comparison of the model will use or SSE if the models possess the same experimental points (N) and parameter numbers of models (). Otherwise, will be employed.

3. Results and Discussion

3.1. Characterization of MIL-101 Samples

Figure 1 shows the XRD patterns of MIL-101 synthesized with the HF/H₂BDC molar ratios of 0.00, 0.25, and 0.75. The characteristic diffractions of the samples matched well with the published XRD patterns of MIL-101 [18]. This means that the obtained materials are MIL-101. However, the peak intensity of the samples synthesized with HF is significantly higher than that of the sample synthesized without HF (MHF0). This could be due to fluorine that acts as a mineralizing agent in the hydrothermal synthesis for the formation of well crystalline microporous materials [31].

The morphology of the obtained material consists of octahedron-shaped crystals with smooth facets (Figure 2). The particle size of MIL-101 increases with the increase in the HF/H₂BDC ratio. The average particle size counted based on 50 particles is 234 nm for MHF0, 364 nm for MHF0.25, and 612 nm for MHF0.75 (Table 1).

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(b)

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The textural properties of the MIL-101 samples were investigated by using nitrogen adsorption/desorption isotherms. The isotherm curves belong to type IV according to IUPAC classification (Figure 3). The BET specific surface area for MHF0.25 is the highest (Table 1), and thus, MIL-101 synthesized with HF/H₂BDC = 0.25 was chosen for adsorption experiments.

3.2. RDB Adsorption on MIL-101

3.2.1. Effect of Initial Concentrations

The RDB kinetics of adsorption on MIL-101 at different initial concentrations in the range of 25–600 ppm is illustrated in Figure 4(a). It is obvious that the adsorption capacity of RDB on MIL-101 increases when RDB initial concentration increases from 25 to 400 ppm. This might be due to the fact that, initially, the sites on the adsorbent surface are less occupied by the dye molecules, and increasing the concentration increases the interaction between the dye molecules and the adsorbent; thus, more dye molecules adsorb on the surface [10, 32, 33]. In addition, the mass transfer driving force becomes larger as the initial concentration increases, and this results in higher adsorption capacity [21]. At higher concentrations (>400 ppm), the adsorption takes place very fast during the first 15 minutes, and then, it slows down and reaches equilibrium at about 150 minutes. Meanwhile, for concentration at 25 ppm, the adsorption reaches equilibrium practically immediately, just after about 10 minutes. This might be because at low dye concentration, the driving force is very small and the adsorption takes place only on the surface of MIL-101, whereas when the dye concentration is high with large driving force, the adsorption also occurs in the pore of the adsorbent, and due to high resistance in the pores, the adsorption becomes slower and reaches equilibrium after a longer period. Furthermore, adsorption might take place in several stages. At a very high dye concentration (600 ppm), the RDB adsorption on MIL-101 does not follow the same pattern as at lower initial dye concentration (Figure 4). This might be the result of forming a colloidal solution at a high concentration of RDB [20, 34].

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(b)

Therefore, the RDB initial concentration from 50 to 400 ppm is suitable for the kinetic study of adsorption on MIL-101. In this kinetic study, Weber’s intraparticle diffusion model [19] was applied to study the adsorption mechanism. The values of q_t at different times were analysed using piecewise linear regressions based on the assumption of one, two, three, and four linear segments. The AIC_C value was the criterion for determining which one is the goodness of fit (Table 2).

The data indicate that the three-linear-segment model has the lowest AIC_C, and therefore, this Weber’s model is the most accurate because for this criterion the lower the value, the more suitable the model. Three distinct steps can be seen on the kinetic curves: (i) instantaneous adsorption of RDB molecules within the first 7–21 minutes, (ii) a gradual attainment of the equilibrium due to the utilization of the all active sites on the adsorbent surface, and (iii) an equilibrium attainment of RDB molecules onto MIL-101 (Figure 4(b)). At the initial concentration of 50 mg·L⁻¹, for example, the intercept of the first linear segment is 0.05, and its 99% confidence interval is (−3.14; 3.23), indicating that the intercept is not significantly different from zero. This strongly suggests that intraparticle diffusion is the rate-controlling mechanism during the first 15 minutes of adsorption. The next two linear segments do not pass through the origin because the 99% confidence intervals of their intersects do not contain zero, indicating that the intraparticle diffusion is not the only rate-limiting step and film diffusion or chemical reaction might take place during these periods of adsorption [20, 33]. This behavior is found for all concentrations. The intraparticle parameters are illustrated in Table 3.

The data indicate that the film thickness (intercept 2 and intercept 3) increases with the increase in initial RDB concentration. This suggests that film diffusion controls the adsorption process in the last two steps. In the first step, the intraparticle diffusion parameter, k_p1, increases as initial RDB concentration increases. These results suggest that intraparticle diffusion controls the rate in the initial step of the adsorption process.

In addition, the nature of the rate-limiting step is also confirmed by plotting the intraparticle diffusion constant, k_p1, versus the first power of the initial concentration. If k_p1 is proportional to the initial dye concentration, the adsorption process is controlled by film diffusion, whereas, if intraparticle diffusion limits the adsorption process, the relationship between dye concentrations and k_p1 will not be linear [20, 35]. For the adsorption of RDB onto MIL-101, the plot of k_p1 versus the initial concentration (C₀) is not linear (R² = 0.875; ), confirming that the intraparticle diffusion mechanism controlled the adsorption in the initial step.

To study the formal kinetics of the RDB adsorption on MIL-101, the experimental data were subjected to pseudo-first-order and pseudo-second-order kinetics in the nonlinear form. The results are shown in Figure 5(a) and Table 4.

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(b)

The experimental points in Figure 5(a) are very far from the first-order model curves, whereas they practically coincide with the second-order kinetic curves. From Table 4, we can see that the pseudo-second-order kinetic model has lower AIC values than the pseudo-first-order kinetic model. This means that the pseudo-second-order kinetic model explains the experimental data more appropriately. These results are consistent with those of other reports [30, 36, 37]. The rate constant k₂ calculated from the pseudo-second-order kinetic model decreases as the initial RDB concentration increases. This indicates that chemisorption is significant in the rate-limiting step, involving valence forces through sharing or exchange of electrons between RDB and MIL-101.

However, as mentioned earlier, in the present study, the adsorption process took place in three steps. Although the pseudo-second-order kinetic model accounts for the chemisorption nature well, it does not support the multisegment adsorption process. Al-Ghouti et al. [20] mentioned this problem and tried to analyse the adsorption as a three-step process with three linear segments on the kinetic plots by using the graphical approach method. Therefore, in this study, we analyse the adsorption process in the same way; that is, the kinetic plot is also divided into three segments each of which follows the pseudo-first-order adsorption kinetics.

The three-step kinetic rate equation was expressed as follows:where , , and are the amount of dye adsorbed at time after the subsequent kinetic steps (mg·g⁻¹); is the amount of dye adsorbed at time = 0; and , , and are the kinetic rate constants associated with each kinetic step. At t = ∞, when the adsorption reaches equilibrium, q_t = q_e, and q_e = q₀ + q₁ + q₂ + q₃. Therefore, (22) can be written as

The values of , , and and , , and can be obtained using nonlinear regression by means of the Statistical Package for Scientific Social 20 (SPSS 20).

The three-nonlinear-segment regressions using the pseudo-first-order kinetic model for the RDB adsorption on MIL-101 are shown in Figure 5(b) and Table 5. High determination coefficients (0.91–0.99) indicate the appropriateness of the model. In addition, the AIC_C values for the pseudo-first-order kinetics with three segments are also the lowest of the three kinetic models (Table 6). This further confirms the best fit of the pseudo-first-order kinetics with three segments with the experimental data. The finding is also consistent with the analysis of the three-step adsorption process using Weber’s intraparticle diffusion model.

3.2.2. Effect of Particle Size and Agitation

To study diffusion kinetics of the RDB adsorption on MIL-101 in terms of particle size, the three-linear-segment regression for the intraparticle diffusion model was applied to analyse the experimental data (Figure 6(a)). The results were the same as those of the effect of initial concentration. Intraparticle diffusion limited the adsorption rate at the initial step, and film diffusion controlled the process in the next two steps. The values of k_p1 are 14.04, 29.94, and 13.55 mg·g⁻¹·min^−0.5 for MHF0, MHF0.25, and MHF0.75, respectively. Theoretically, the intraparticle diffusion constant, k_p1, versus the inverse particle diameter, d⁻¹, did not give a straight line, and the conclusion for this is that the intraparticle diffusion was not the only operative mechanism [20]. In fact, in our study, this line was not linear () although MIL-101 is a porous material; hence, we cannot rely on the particle size (external surface area) to confirm the adsorption mechanism. Therefore, the intraparticle diffusion mechanism controlled the initial step of the adsorption process. As can be seen from Figure 6(a), the adsorption capacity depends on the specific area rather than the particle size. This is because, for porous materials, the external surface contributes very little to the total surface area. In terms of particle size, only external surface area is concerned.

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Stirring speed affects not only the distribution of the dye molecules in the bulk solution but also the formation of the external boundary film. Increasing stirring speed decreases the film thickness and thus the resistance to mass transfer around the adsorbent particle and increases the mobility of the whole system [38]. The effect of the stirring speed on RDB adsorption on MIL-101 was carried out with three values: 200, 300, and 400 rpm (Figure 6(b)). It is evident that the adsorption capacity increased when the stirring speed increases from 200 rpm to 300 rpm and remained practically stable at 400 rpm. As the stirring speed increases the diffusion rate, the resistance of the solution becomes small. After a certain stirring rate, the external resistance no longer affects the sorption process.

3.2.3. Thermodynamic Studies

Temperature significantly affected the RDB adsorption over MIL-101. When the temperature increased from 301 K to 333 K, the adsorption capacity increased rapidly from 120 mg·g⁻¹ to 190 mg·g⁻¹ (Figure 7(a)). This indicates that the RDB adsorption on MIL-101 is an endothermic process. Similar results were observed in the adsorption of uranine [9] and methyl orange [32] on MIL-101.

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It is obvious that high temperature increased the diffusion rate of the dye molecules across the external boundary layer and in the internal pores of the adsorbent particle. This was the result of the decrease in the viscosity of the solution. In addition, the increase in adsorption capacity could also be ascribed to the increase in the number of active sites on the MIL-101 surface due to the decrease in the hydrogen bonding between adsorbed water and the adsorbent making more sites available for RDB molecules.

The pseudo-second-order kinetic model was more consistent with the kinetic data than the pseudo-first-order kinetic model in the temperature range of 301 K to 333 K. Hence, the rate constant k₂ was used to calculate the thermodynamic parameters. The E_a value obtained from the slope of the linear plot of ln k₂ versus T⁻¹ (F(3) = 59.15; R² = 0.98, ) (Figure 7(b)) was 50.39 kJ·mol⁻¹. This large activation energy (over 42 kJ·mol⁻¹) implies that chemisorption controlled the adsorption of RDB on MIL-101.

The thermodynamic parameters of the system, namely, ΔH⁰, ΔS⁰, and ΔG⁰ were evaluated using the van’t Hoff equation to determine the spontaneity of the adsorption process. The positive value of ΔH⁰ (Table 7) suggested an endothermic adsorption process. The positive value of ΔS⁰ indicated the increase in the randomness at the solid-liquid interface during the adsorption of RDB molecules on the adsorbent [39]. The large negative values of ΔG⁰ strongly recommended the spontaneous RDB adsorption on MIL-101. The more negative value at higher temperatures suggested that the spontaneity increased with temperature. As the change of Gibbs free energy was negative and accompanied by the positive standard entropy change, the adsorption reaction was spontaneous with high affinity.

3.2.4. Effect of pH

The pH of the solution affects the dye adsorption process because it can alternate both dye ionization and the ionic state of the surface of the adsorbent. Figure 8(a) presents the effect of pH on RDB adsorption from aqueous solutions. The RDB adsorption capacity of MIL-101 increased slightly with pH from 3 to 5, followed by a significant increase with pH from 5 to 9. The pH_pzc (the point of zero charge) of MIL-101 determined by the pH drift method [40] is around 5 (Figure 8(b)). This pH_pzc implies that the surface of the MIL-101 is positively charged when pH of the solution is below 5, whereas the surface of adsorbent becomes negatively charged at pH above 5.

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Increasing pH led to an increase in adsorption capacity, suggesting that the adsorption could follow a mechanism other than electrostatic interaction. The π-π stacking interaction between the aromatic rings of the RDB and the aromatic rings of terephthalate in the MIL-101 framework was also thought to contribute to the RDB adsorption capacity. In addition, the coordination of the oxygen of the carboxyl group in the RDB molecules with the unsaturated Cr(III) ions in the MIL-101 framework is also responsible for more efficient adsorption. A possible mechanism of RDB adsorption on MIL-101 is illustrated in Scheme 2.

3.2.5. Adsorption Isotherms of RDB on MIL-101

To describe the adsorption isotherms, Langmuir, Freundlich, Redlich–Peterson, Sips, and Toth equations were selected for use in this study. The determination of parameters of isotherm models is often based on the linear regression. However, linear regression requires the transformation of the original equation into a linear form that induces a problem related to abuse R². For example, the popular linear form of the Langmuir model is , in which is present in both independent and dependent variables [41]. Some papers [42, 43] reported that the linear form is less accurate than the nonlinear form in some cases of isotherm sorption as well as sorption kinetics. For these reasons, the isotherm equations in the nonlinear form are used in this study. Figure 9 shows the graphs that plot q_e versus C_e using the Langmuir, Freundlich, Redlich–Peterson, Sips, and Toth models. These models displayed lines around the experimental data, indicating that they all could describe the experimental data well.

The parameters of the isotherm models calculated using nonlinear regression are listed in Table 8. Except q_m derived from the Sips model (290.15 mg·g⁻¹), the values of q_m from the Redlich–Peterson and Toth models are fairly similar to that of q_m obtained from the Langmuir model due to the parameter of n being close to 1.

Based on the values of SSE as well as the coefficient of determination, we can see that the Langmuir, Redlich–Peterson, and Toth models provide a higher goodness of fit than the Sips and Freundlich models (Table 8).

To compare models with the same parameters and experimental points, SSE or R² are frequently utilized to estimate the goodness of fit. As a result, it is obvious that the experimental data fit the Langmuir model better than the Freundlich model. However, for models with a different degree of freedom, Akaike’s information criterion [44] is used instead.

Table 9 shows the comparison of the Langmuir model with other models in the study. The value of ER (15.1, 15.8, 28.6, 1875.1) indicates that the Langmuir model is more appropriate than the Toth, Redlich–Peterson, and Freundlich models, implying that the monomolecular-layer nature is prevalent for the adsorption of RDB onto MIL-101.

It is obvious that the piecewise linear regression is a useful approach to analyse the multilinearity. In order to find out the parameters in regression equations, the initial variables should be provided. If the initial variable is as far away as the real parameters, the solving equation is easy to go wrong due to finding the local minimum. This problem needs to study further. In this study, using AIC is proved to be effective for evaluating the goodness of fit for models which have a different number of parameters and experimental points. However, the application of AIC in adsorption filed is limited. Clarification of the meaning behind the AIC should be clarified.

3.2.6. Reusability of MIL-101

In order evaluate the reusability of MIL-101 in the removal of RDB, used MIL-101 samples were regenerated by washing with a 0.25 M NaOH solution for 5 h under sonication and drying for 10 hours at 100°C. Three generations were performed, and the RDB adsorption capacity decreases slightly (96.5%) and remained at around 120 mg·g⁻¹ (Figure 10(a)). Furthermore, MIL-101 seems to be stable under adsorption conditions since the XRD patterns of generated MIL-101 samples remained practically unchanged (Figure 10(b)).

(a)

(b)

4. Conclusions

MIL-101 was synthesized using the hydrothermal process. The particle size of MIL-101 could be controlled by adjusting the molar ratio of HF/H₂BDA. MIL-101 can serve as a useful adsorbent for RDB under batch conditions. The synthesized MIL-101 material displays high adsorption capacity and can be reused. Piecewise linear regression allows to objectively analyse the experimental data using Weber’s intraparticle diffusion and pseudo-kinetic adsorption models during the sorption process. The results of kinetic analysis suggested that the mechanism of the sorption of RDB on MIL-101 might take place throughout the three steps: (i) film diffusion that dominates at the beginning of the process, (ii) chemisorption that monitors the subsequent period of the process, and (iii) intraparticle diffusion, where the adsorption significantly slowed down. The best fit of the pseudo-first-order kinetics with three segments with the experimental data is consistent with the analysis of the three-step adsorption process using Weber’s intraparticle diffusion model. Akaike’s information criterion was employed to compare different isotherm models with a different degree of freedom. The equilibrium data of RDB onto MIL-101 fitted well to the Langmuir model rather than the Freundlich, Sips, Toth, and Redlich–Peterson models. As the change of Gibbs free energy was negative and accompanied by the positive standard entropy change, the adsorption process was spontaneous with high affinity.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

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Copyright © 2018 Vo Thi Thanh Chau et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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