Elimination of Congo Red Dye from Industrial Wastewater Using <i>Teucrium polium L.</i> as a Low-Cost Local Adsorbent

Alamrani, Nasser A.; AL-Aoh, Hatem A.

doi:https://doi.org/10.1155/2021/5728696

Adsorption Science & Technology

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Abstract Introduction Materials Results and Discussion Conclusions Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2021 | Article ID 5728696 | https://doi.org/10.1155/2021/5728696

Elimination of Congo Red Dye from Industrial Wastewater Using Teucrium polium L. as a Low-Cost Local Adsorbent

Nasser A. Alamrani¹and Hatem A. AL-Aoh¹

Academic Editor: George Kyzas

Received19 May 2021

Revised18 Jun 2021

Accepted25 Jun 2021

Published14 Jul 2021

Abstract

A novel adsorbent prepared from the leaf powder of Teucrium polium L. (TPLLP) was characterized and its ability for adsorption of Cong red (CR) was inspected. Influences of CR concentration, adsorbent dosage, time of agitation, pH of solution, and temperature on the performance of this adsorption were also examined. Three models of kinetic along with three different isotherm models were applied for analyzing the empirical data of this adsorption. Additionally, the thermodynamic constants of were decided. The surface area, pore volume, pore size, and pH_ZPC of Zn/Cu-TPLLP were found to be 2.6436 m².g^-1, 0.013317 cm³.g^-1, 527.393 Å, and 8.8, respectively. The achieved outcomes indicate the positive influence of temperature, concentration of CR in the range of 20 to 900 mg/L, adsorbent mass in the range of 0.005 to 0.02 g, time of adsorption from 0 to 120 min, and pH from 5.5 to 8.5. Models of the 2^nd order with and Langmuir with were the best among the other kinetic and isotherm models applied in this research. Moreover, superior capacities of 526.32, 666.67, and 909.09 (mg.g^-1) were stemmed at 27, 42, and 57°C, respectively. The outcomes of the thermodynamic evidenced that this adsorption is spontaneous and a heat absorber.

1. Introduction

The dye of Congo red (CR) is known as typically anionic diazo dye having four different color-assisted functional groups [1], which has an IUPAC name of disodium 4-amino-3-[4-[4-(1-amino-4-sulfonato-naphthalen-2-yl) diazenylphenyl] phenyl] diazenyl-naphthalene-1-sulfonate [2] and has various molecular structures in the aqueous solutions that differ in their pH [2]; it is highly soluble in water and stable in air and light [3]. CR dye is used in laboratories as a pH indicator, histological dye, amyloidosis diagnosis, and for testing the contents of HCl in gastric [3]. This dye is also used in various industries like industry of textile due to its significant affinity to fibers of cellulose, papermaking, and industry of plastic, cosmetics, and pharmaceuticals [4, 5]. CR is a member of benzene compounds and contains in its structure aromatic amines; therefore, it will be converted to carcinogenic materials in the environment [3, 6]. Moreover, benzidine produced from metabolizing of CR poses hazard effects on human health such as irritation of gastrointestinal, eye, and skin [3]. Benzidine also causes clotting of blood, somnolence, and breathing problems [3]. Consequently, it is necessary to remove CR from sewage of those laboratories and industries before their discharge to the aquatic system. Thus, conventional biological methods have been established for decolorization of CR from the sewages of laboratories and industries, e.g., fungi of white rot [7], and foams of polyurethane and polypropylene [8] were applied for biodegradation of CR. It was reported that the biodegradation efficiency of CR is insufficient due to different aromatic structures and synthetic origin of this dye [9]. Therefore, other traditional techniques like electrocoagulation [10], coagulation by Fe₃O₄ [11], membrane filtration [12], and precipitation by chemical agents [13] were also utilized for removing of CR from water. The high cost and low removing performances of these methods prove that their usage is ineffective. Photocatalytic degradation of CR by activated hydrotalcites [14], cobalt ferrite nanostructures [15], nickel oxide nanoparticles [16], nanocomposite [17], and zinc oxide nanoparticles [18] was also investigated. Despite the effectiveness of the photocatalytic degradation techniques towards CR, the harmfulness of this dye may be less than that of its degradation products.

Additionally, various sorbents such as activated carbon prepared from different materials [19–21], different clays [22] carbon loaded by nanoparticles of cobalt [23], magnetic nanocomposites of Co₃O₄ and SiO₂ [24], binary oxide of iron zirconium [25], nanoparticles of MgO [26], and nanoparticles of SnO₂ [27] were used to purify the sewages from CR. In comparison with other methods, the adsorption of CR by these adsorbents was found to be the best in terms of its efficiency, easy design, and operation [28]. Therefore, adsorption was selected in this study as the standard technique for removing of CR from synthetic aqueous solutions.

Although the nanoparticles of metallic oxides and activated carbon have a high adsorptive performance, their usages become limited due to the high costs of their production. Hence, several low or uncostly materials were applied as effective adsorbents for CR elimination from waters, e.g., hydrothermal-treated mushroom [1], powder of shrimp shell [2], tea waste [29], bottom ash and de oiled soya [3], and conjugates of sodium alginate-Chlorella polypyrrole-Chlorella[30]. The outcomes of these studies indicate that there are big differences between the adsorption performances of these cheap adsorbents towards CR. Therefore, other works should be carried out to investigate CR adsorption by other low-cost sorbents.

Teucrium polium L. (TPL) or germander is a herbal plant that has been utilized for more than 2000 years as traditional herbal remedies for their antifungal, carminative, antispasmodic, antipyretic, anti-inflammatory activity, and their ability to decrease high blood pressure [31]. This herbal plant belongs to Lamiaceae family that contains around 300 species and the flowering time of these herbs is between June and August. These species are abundantly distributed on hills and mountains in different locations such as Mediterranean countries, Southwest Asia, North Africa, and Europe [31, 32]. This plant is rich in flavonoids and commonly known in Saudi Arabia as Ja’adeh [32].

In the case of wastewater treatment, TPL has been used previously for preparation of Fe₂O₃ nanoparticles, which are used as a catalyst for photodegradation of methyl orange dye [33] and as an adsorbent for arsenic (III) removal from the aqueous solutions [34].

Despite the cheapness of this herbal plant and its availability in a considerable amount in many different countries, especially in Tabuk City and others in Saudi Arabia, there is no attempt that has been carried out till now to use the Teucrium polium L. leaf powder (TPLLP) as a new adsorbent for the removal of hazardous dyes from water or wastewater. Therefore, the main object of this work is to evaluate the adsorption efficiency of CR by using TPLLP as a novel, available, and cheap adsorbent. To achieve this aim, the leaf powder of this herb was modified by copper sulfide, zinc chloride (ZnCl₂), and oxalic acid (HO₂CCO₂H); the modified and unmodified samples were characterized and the adsorptive performances of CR by these adsorbents were compared to select the best one. After that, influence of experimental conditions along with constants of kinetics, isotherms, and thermodynamic was examined for adsorption of CR by the best adsorbent prepared and tested in this work.

2. Materials and Methodology

2.1. Materials and Chemical Agents

The leaves of Teucrium polium L. (TPL) were supplied by a market located in Tabuk City, Saudi Arabia. Chemical reagents such as hydrochloric acid HCl (37%), sodium hydroxide NaOH with ZnCl₂ with , HO₂CCO₂H with , CuS with , and Na₂CO₃ with were obtained from Sigma-Aldrich and used in this research.

2.2. Modification of TPLLP

The leaves of TPL were twice washed by distilled water, dried in an oven, and then converted to powder by electric grinder (TPLLP). A 100 g of TPLLP was refluxed with 1 L of 20% of ZnCl₂ at the boiling point for 180 min, and after this time, the mixture was left at room temperature for cooling. The cooled mixture was filtered and the remaining solid was heated with 250 mL of 2 M HCl for 90 min to remove the excess amount of ZnCl₂. Then, the solid part of the new mixture was disconnected by filtration and repeatedly rinsed by distilled water. Then, the clean solid was put for 30 h in an oven at 130°C for dehydration. Finally, the dehydrated solid was grinded, sieved to get homogeneous particles, and labeled as Zn-TPLLP.

Similar conditions and processes were applied for the mixture consisting of 100 g TPLLP and 50 g of CuS. The resulted adsorbent in this case was labeled as Zn/Cu-TPLLP.

A 100 g of TPLLP was also refluxed with 1 L of 20% oxalic acid solution by applying the same experimental conditions and procedures mentioned above. The resulted sample was named as Ox-TPLLP.

2.3. Characterization of Adsorbents

At a 10 kV accelerating voltage, the modified and unmodified TPLLP samples were scanned by SEM equipment to identify the surface morphology of these adsorbents. These adsorbents were also scanned by the instrument of FT-IR (Nicolet iS5 of Thermo Scientific FT-IR, USA) to detect the types of the functional groups on the surface of these samples.

The technology of BET (NOVA-2200 Ver. 6.11) was applied at 77.35 K for 22 h to estimate the surface area and porosity of these adsorbents. Furthermore, five solutions of 0.05 M Na₂CO₃ with different initial values of pH (2, 4, 6, 8, and 10) () were prepared. 40 mL of each solution was mixed with 0.2 g of the ideal adsorbent in a 150 mL plastic bottle. The bottles were shaken in shaker incubators at 27°C and 175 rpm for 26 h. Then, each solution was separated by filtration and the final pH (pH_f) of each one of these five solutions was measured using a pH meter. Finally, the values of () were computed and plotted against the values of to assess the pH_ZPC value of this adsorbent.

2.4. Adsorption Experiments

2.4.1. Determination of the Ideal Adsorbent

To identify the best and the most effective adsorbent prepared in this work towards CR, 20 mL of 100 mg/L CR solution was mixed with 0.03 g of raw leaf powder of TPL (TPLLP) in a 30 mL amber bottle. The sealed amber bottle was agitated by a shaker incubator for 30 h at 180 rpm and 27°C. Then, the mixture was filtered and the Jenway UV-6800 UV-Vis spectrophotometer was applied for measuring the balance concentration of CR in the filtrate at 500 nm. Similar experiments were carried out for the adsorption of this dye by the other three adsorbents (Zn-TPLLP, Zn/Cu-TPLLP, and Ox-TPLLP). Equations (1) and (2) were used for computing the CR percentage removal and amounts of CR adsorbed at equilibrium (, mg.g^-1) by each of these adsorbents. where and are the initial and final concentrations of CR solution, respectively.

2.4.2. Influence of Experimental Conditions

The experiments of CR adsorption by the ideal adsorbent (Zn/Cu-TPLLP) were achieved in a batch system to examine the influence of the most important factors like Zn/Cu-TPLLP dosage (0.005-0.035 g), contact time (0-420 min), and pH (5.5-11.5) as the CR solution color will be changed to blue at pH less than 5, CR concentration (20-1000 mg.L^-1), and temperature (27-57°C) on the adsorption. All of these experiments were carried out by mixing 20 mL of CR solution with the required amount of Zn/Cu-TPLLP in amber bottles (30 mL). Then, the sealed amber bottles were shaken at 180 rpm in a shaker incubator. After the required time for each experiment, the suspensions were filtered and the remaining CR concentrations were measured as mentioned in Section 2.2. The experimental conditions applied in this work are listed in Table 1.

Equations (2) and (3) are used for the calculation of the amount of CR adsorbed at equilibrium (, mg.g^-1) and time (, mg.g^-1), respectively. where is the CR concentration (mg.L-1) at contact time . is the mass of Zn/Cu-TPLLP (g), and is the volume of CR solution (L).

2.4.3. Kinetic Studies

The experimental results of Section 2.3 for adsorption of 60, 150, and 300 mg.L^-1 of CR solutions by Zn/Cu-TPLLP at 27°C and various times (0-420 min) were analyzed by the linear forms of three different kinetic models (Table 2) to determine the parameters of these models. Then, the obtained kinetic data were used for the investigation of the rate and mechanism of this adsorption.

2.4.4. Isotherm Studies

The experimental data of Section 2.3 for adsorption of 20-1000 mg/L CR solutions by Zn/Cu-TPLLP (0.02 g) at a contact time of 22 h and various temperatures (27, 42, and 57°C) were analyzed by the linear equations of Langmuir, Temkin, and Freundlich isotherm models (Table 3) to evaluate the performance of this adsorption and to characterize the surface of Zn/Cu-TPLLP. Moreover, the values of (parameter of equilibrium) related to the fundamental characteristics of the Langmuir model were computed by applying Equation (4). where is the Langmuir constant and is the highest CR initial concentration.

2.4.5. Thermodynamic Studies

The thermodynamic constants (, , and ) were assessed from the outcomes of Section 2.3 for adsorption of 100, 150, 200, 300, and 500 mg.L^-1 CR solutions based on Equations (5) and (6). where is the enthalpy change, is the entropy change, is the change in standard free energy, is the temperature of adsorption (K), and is the universal constant of gases (8.314 J/K mol).

3. Results and Discussion

3.1. Adsorbent Characterization

Figures 1(a)–1(d) are the SEM images for adsorbent samples labeled as TPLLP, Ox-TPLLP, Zn-TPLLP, and Zn/Cu-TPLLP, respectively. In comparison between the image of an unmodified adsorbent (a) and images of the other three modified samples (b), (c), and (d), it can be detected that the surface of TPLLP is significantly changed due to the modification process, where most of folds in the modified adsorbent were collapsed and their structures became distracted. Moreover, the surfaces of the modified adsorbents contain many heterogeneous holes and pores which are supportive to the adsorption phenomena. Figure 1 also reveals that the density of the micropores on the adsorbent surface modified by ZnCl₂ and CuS (Zn/Cu-TPLLP) is higher than that of the other three adsorbents.

(a)

(b)

(c)

(d)

The spectra of FT-IR for unmodified and modified TPLLP are demonstrated in Figures 2. This figure reveals that the unmodified sample of TPLLP has seven peaks at 3335.93 cm^-1 for stretching the hydrogen banded of O–H, 2923.91 cm^-1 for C–H alkyl stretching, 2854.17 cm^-1 for stretching of C–H, 1727.26 cm^-1 for C = O stretching (aliphatic aldehydes), 1513.56 cm^-1 for N-H (2°-amide) II band, 1158.35 cm^-1 for stretching of C–O, and 1025.46 cm^-1 for bending of C–H in-plane. Similar peaks with small shifting can be detected in the case of Zn-TPLLP and Zn/Cu-TPLLP samples (Figure 2). Figure 2 also demonstrates that three new peaks appeared in the case of Ox-TPLLP at 1616.92, 1318.54, and 780.67 cm^-1. The presence of these various functional groups on the surface of these adsorbents implies the chemical activity of these adsorbents.

According to the results of the BET surface analyzer (0.3806 m².g^-1, 0.001467 cm³.g^-1, 151.065 Å), (0.7680 m².g^-1, 0.006674 cm³.g^-1, 157.279 Å), (1.5875 m².g^-1, 0.007757 cm³.g^-1, 400.197 Å), and (2.6436 m².g^-1, 0.013317 cm³.g^-1, 527.393 Å) are the surface area, pore volume, and pore size of TPLLP, Ox-TPLLP, Zn-TPLLP, and Zn/Cu-TPLLP, respectively. This means that the surface area and pore characteristics of . This confirms that the hydrothermal modification of TPLLP by ZnCl₂ and CuS has an effective role in the improvement of the porosity and surface area of this raw material.

Figure 3 depicts the relationship between the values of and (). The pH solution value at which the surface of this ideal adsorbent will be neutrally charged is 8.8.

3.2. Results of Adsorption Experiments

3.2.1. Adsorbent Performance

The percentage removal of CR from aqueous solutions by TPLLP, Ox-TPLLP, Zn-TPLLP, and Zn/Cu-TPLLP adsorbents was determined to be 17.87, 45.11, 54.94, and 78.75 percent, respectively. Moreover, the values of 11.91, 30.08, 45.06, and 52.50 (mg.g^-1) are the amounts of CR adsorbed at equilibrium () by these adsorbents and the same order. These values prove that the effectiveness of these adsorbents for the removing of CR is as follows:

This can be explained by the surface areas and pore characteristics of these adsorbents which are augmented in the same order (Section 3.1). The outcomes of this section confirm that Zn/Cu-TPLLP is the ideal sample that can be applied for CR adsorption. Thus, the other experiments of this work were conducted by using Zn/Cu-TPLLP only.

3.2.2. Influence of Zn/Cu-TPLLP Dose

To define the optimal mass of Zn/Cu-TPLLP that will be required for the adsorption of CR dye and to examine the dosage influence, the values of the % removal of CR from its solutions were plotted against Zn/Cu-TPLLP doses (Figure 4). This figure shows augmenting the values of CR with increasing the mass of Zn/Cu-TPLLP in the range of (0.005-0.02 g). This increment was resulted from increasing the active sites of the adsorbent which are directly proportional with the amount of an adsorbent [35]. Figure 4 also displays that there is no significant change in the value of when the adsorbent mass increased from 0.02 g to 0.035 g because the adsorbent molecules in the case of their high doses will be assembled together to form a cluster [36]. For this, 0.02 g of Zn/Cu-TPLLP was selected as the ideal dose in this work. Similar trends were reported for the adsorption of MnO₄^- on CuS surface [37].

3.2.3. Impact of pH

The process of adsorption is strongly affected by the solution pH of the adsorbate, as the adsorbent charge and ionization degree of the dye molecules depend on the value of pH. For this reason, the influence of this factor was considered in this work (Figure 5). As indicated in Figure 5, (mg.g^-1) was positively affected when pH elevated from 5.5 to 8.5. This was due to the strong attraction between the anions of CR () and the positive charges on the surface of Zn/Cu-TPLLP (). On the contrary, (mg.g^-1) was negatively influenced by increasing pH value over 8.5 as a result of the strong repulsion between the negative ions of CR and the negative charges of this adsorbent. Similar outcomes were reported for the adsorption of CR on the surface of some solid wastes [3].

3.2.4. Kinetic Studies

Figure 6 illustrates the contact time impact on the adsorption of CR solution (60, 150, and 300 mg/L) by a fixed mass of Zn/Cu-TPLLP (0.02 g). According to this figure, there are three different adsorption stages, where the adsorption amount rapidly increased in the 1^st stage (0-10 min), gradually increased in the 2^nd stage (10-120 min), and almost was constant after 120 min (3^rd stage). This proves that most of the sites were vacant at the first stage of this adsorption, and then, CR molecules gradually accumulated on these sites till fully occupied. The same outcomes were observed for CR adsorption by tea waste [29]. Although Figure 6 demonstrates that the equilibrium of this adsorption was achieved in 2 h, other experiments were performed at 22 h to ensure that all adsorption constants have been essentially studied at equilibrium.

Moreover, the slopes and intercepts of the plots of Figure 7 (kinetic model of the 1^st order), Figure 8 (kinetic model of the 2^nd order), and Figure 9 (kinetic model of intraparticle diffusion) were applied for computing the dynamic parameters of this adsorption. The calculated values were recorded in Table 4 for the first- and second-order models and in Table 5 for intraparticle diffusion model. In comparison between the parameter values of the first- and second-order models (Table 4), it can be seen that (correlation coefficient) values of the first order are less than those of the second order and the empirical values of (_{, exp}) are significantly similar to the values of calculated from the slopes of the second-order plots (_{, cal}). These outcomes prove that the kinetic model of the pseudo 2^nd order can be applied for describing the kinetic empirical data for this adsorption. This confirms that this adsorption occurred due to the chemical interactions between the functional groups of Zn/Cu-TPLLP and molecules of CR [38]. The same outcomes were observed for CR adsorption by conjugates of sodium alginate-Chlorella polypyrrole-Chlorella[30]

Figure 9 reveals that each one of these plots is not linear for the total interval of time; none passed from the origin point and has two linear parts which have significant values of . These results are evidence that the rate of this adsorption is controlled by intraparticle diffusion and other mechanisms [39]. Furthermore, the small values of C constant (Table 5), which are associated with the adsorbent layer thickness, prove that the external diffusion of CR molecules has a negligible role in the controlling of this adsorption rate [40]. Similar trends were noted for methylene blue adsorption by ZnCl₂-modified Neem [41] and Lamiaceae [42].

3.2.5. Outcomes of Isotherms

The results associated with the influences of solution temperature and concentration on the performance of this adsorption are represented in Figure 10. The plots of this figure show that the adsorption of CR by Zn/Cu-TPLLP was positively influenced by the solution temperature because the CR solution viscosity and the movement energy of CR molecules decrease and increase, respectively, with rising temperature [43]. Figure 10 also shows that the values of at each temperature were regularly augmented by increasing the CR concentration from 20 to 800 mg.L^-1. This can be explained by the fact that increasing the concentration of adsorbate will improve the force of dynamics that reduces the resistance of the mass movement of CR molecules between the adsorbate solution and the adsorbent surface [44]. Moreover, there is no variation in the values of that can be seen when CR concentration increased above 800 mg.L^-1 because all adsorption sites become full at this high concentration.

Furthermore, the analyzed experimental data of the isotherms of this adsorption are presented in Figure 11 (Langmuir model), Figure 12 (Freundlich model), and Figure 13 (Temkin model). Intercepts and slopes of the plots of these figures were used for calculation of the values of the isotherm factors recorded in Table 6. Langmuir model has the highest value of compared to the other two models (Table 6), which confirms that the empirical data of this adsorption are better to be described by Langmuir model. According to these outcomes, it can be suggested that this adsorption is a monolayer and the adsorption sites of Zn/Cu-TPLLP are homogeneous [45]. Additionally, all values of (dimensionless adsorption factor) and (Table 6) are less than unity, which confirms that the empirical conditions used in this adsorption were suitable [46]. Similar outcomes were reported for the adsorption of CR on the surface of some solid wastes [3] and hydrothermal-treated shiitake mushroom [1].

Moreover, high adsorption capacities of 526.32, 666.67, and 909.09 (mg.g^-1) (Table 6) were obtained at the temperatures of 27, 42, and 57°C, respectively. This proves that Zn/Cu-TPLLP as a cheap and effective adsorbent will meet special interesting in the purification processes of wastewaters and water from CR.

3.2.6. Thermodynamic Outcomes

The values of for adsorption of 100, 150, 200, 300, and 500 (mg.L^-1) CR solutions by 0.02 g of Zn/Cu-TPLLP were calculated and plotted vis. (Equation (5)) (Figure not shown). Slopes and intercepts of the resulted curves were used for evaluating the and values, respectively. Then, the values of at each temperature were calculated from the obtained values of and based on Equation (6). The calculated values of these parameters (, , and ) are listed in Table 7. The negative values imply that the adsorption of CR by Zn/Cu-TPLLP in the range of 300-330 K is spontaneous [2]. Endothermic adsorption of CR by this adsorbent can be confirmed by the positive [46], which is agreed well with the outcomes of Section 3.2.5 (effect of temperature part). Additionally, values are in the range of 53.229-63.024 kJ.mol^-1 (higher than 20.9 kJ.mol^-1), implying that CR was chemically adsorbed on the surface of Zn/Cu-TPLLP [47]. This is in consistent with the kinetic part results. Furthermore, and positive values prove that the force of driving for this adsorption is effected by rather [48].

3.3. Comparison with Other Low-Cost Adsorbents

The capacities of CR adsorption by Zn/Cu-TPLLP and other common low-cost adsorbents are given in Table 8. As shown, Zn/Cu-TPLLP, due to its significant chemical activity, has adsorption capacity higher than those of the common low-cost adsorbents used for removal of CR from the aqueous solutions before this work. Thus, the low cost of Zn/Cu-TPLLP is along with its higher adsorptive performance which confirms the importance and novelty of this adsorbent among the other low-cost adsorbents previously used for removing of CR from wastewaters.

4. Conclusions

In this research, the leaf powder of Teucrium polium L. (TPLLP) was modified by oxalic acid, CuS, and ZnCl₂. The modified and unmodified samples were characterized and tested for adsorption of Congo red (CR). The sample modified by the mixture of CuS and ZnCl₂ (Zn/Cu-TPLLP) was the best () among these four adsorbents. Thus, Zn/Cu-TPLLP was selected in this work as a novel adsorbent for adsorption of CR dye from the aqueous solutions. The surface area, pore volume, pore size, and pH_ZPC of Zn/Cu-TPLLP were found to be 2.6436 m².g^-1, 0.013317cm³.g^-1, 527.393 Å, and 8.8, respectively. Impacts of temperature, pH, concentration of CR solution, dosage of Zn/Cu-TPLLP, and contact time on this adsorption were studied. It was noted that this adsorption is positively affected when temperature, pH, adsorbent dose, CR concentration, and time of contact were augmented in the ranges of 27-57°C, 5.5-8.5, 0.005-0.02 g, 20-900 mg.L^-1, and 0-120 min, respectively. The capacities of this adsorption almost were equal when CR concentration, Zn/Cu-TPLLP dosage, and time of adsorption were increased over 900 mg.L^-1, 0.02 g, and 120 min, correspondingly. Additionally, it was found that this adsorption negatively influenced when pH increased in the range of 8.5-11. Kinetic and isotherm results proved that this adsorption was described well by the kinetic model of the 2^nd order and the isotherm model of Langmuir. Kinetic and thermodynamic outcomes confirmed the chemisorption nature of CR by Zn/Cu-TPLLP. Spontaneous and endothermic properties of this adsorption were proved by the results of thermodynamic. The high capacities of this adsorption (526.32, 666.67, and 909.09 mg.g^-1) imply that Zn/Cu-TPLLP will meet special interesting in the field of polluted water treatment among the other low-cost adsorbents.

Data Availability

Completely, data produced or investigated during this work were involved in this submitted article.

Conflicts of Interest

The authors confirmed that there are no probable conflicts of interest that impact the work reported in this paper.

Acknowledgments

The authors are very appreciative to the Deanship of Scientific Research at Tabuk University for funding the work through new faculty research/funding (Project No. S-0095-1441H).

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Copyright © 2021 Nasser A. Alamrani and Hatem A. AL-Aoh. 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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