Characterization of the LDH@Mnt

XRD traces of Mnt, LDH, 1-LDH@Mnt, 3-LDH@Mnt and 5-LDH@Mnt are shown in Fig. 1a. In the XRD trace of LDH, the characteristic peaks of (003), (006), (018) and (013) located at 11.4, 23.1, 34.4 and 61.5°2θ, representing the LDH crystal structure, were observed. In the XRD trace of Mnt, the characteristic peaks of (001), (002) and (010) are located at 7.8, 20.1 and 63.3°2θ. In the XRD traces of 1-LDH@Mnt, 3-LDH@Mnt and 5-LDH@Mnt, the characteristic peaks of Mnt and LDH were present in all of compound samples, demonstrating the successful combination of LDH and Mnt, and there was no phase transition during the preparation process (Wu et al., Reference Wu, Sun, Wang, Lu, Tang and Gao2023).

Figure 1. (a) XRD traces and (b) FTIR spectra of Mnt, LDH, 1-LDH@Mnt, 3-LDH@Mnt and 5-LDH@Mnt.

The samples of Mnt, LDH, 1-LDH@Mnt, 3-LDH@Mnt and 5-LDH@Mnt were tested using FTIR spectroscopy, and the results are shown in Fig. 1b. The peaks at 3624, 3444 and 1631 cm^–1 were attributed to the hydroxyl stretching vibration (Wu et al., Reference Wu, Sun, Wang, Lu, Tang and Gao2023), the interlayer water stretching vibration and the bending vibration of Mnt and LDH, respectively. The high-intensity absorption band at 1029 cm^–1 represent the characteristic Si–O peak in the silico-oxygen tetrahedron of Mnt (Wu et al., Reference Wu, Sun, Wang, Lu, Tang and Gao2023). The characteristic peaks at ~1369 and 800 cm^–1 represent the N–O vibration of nitrate in the interlayer and the metal oxide vibration of LDH, respectively. In the results for 1-LDH@Mnt, 3-LDH@Mnt and 5-LDH@Mnt, the characteristic peaks of Mnt and LDH in all of the composite samples were observed, indicating that the LDH structure was loaded onto Mnt using in situ method and that the composite samples were prepared successfully.

The specific surface and pore radius distribution of Mnt, 1-LDH@Mnt, 3-LDH@Mnt and 5-LDH@Mnt were analysed using N₂ adsorption/desorption experiments, and the results are shown in Fig. S2 and Table 1. Compared with Mnt, the specific surfaces of the LDH@Mnt samples were greater because the mutual support of the LDH and Mnt layers improved the pore structure, and the specific area of 3-LDH@Mnt was higher than those of the other samples. In addition, from the pore-size distribution results, 3-LDH@Mnt also possessed a greater micropore structure than the other samples, indicating that the composite sample had a favourable pore structure and was conducive to the adsorption of pesticides.

Table 1. Structural characteristics of Mnt, 1-LDH@Mnt, 3-LDH@Mnt and 5-LDH@Mnt.

The morphologies of samples 1-LDH@Mnt, 3-LDH@Mnt, 5-LDH@Mnt and Mnt were investigated using SEM, and the findings are presented in Fig. 2. In Fig. 2a,b, both LDH and Mnt layers are presented, revealing that the composite sample of LDH@Mnt was synthesized successfully using the in situ method. Compared with the morphology of Mnt, the presence of LDH loosened the Mnt layers. However, on account of the low loading amount of LDH, the structure of LDH with its small size was formed on the surface of Mnt. The LDH and Mnt layers could not support each other, resulting in the layers collapsing and becoming stacked. As shown in Fig. 2c,d, with the increased LDH loading amount and the growth of the formed LDH structure, LDH and Mnt layers supported and interpenetrated each other to form a porous structure, overcoming the problems of particle aggregation and layer stacking. Hence, in the 3-LDH@Mnt sample, Mnt modified by the LDH layer demonstrated a significantly enlarged specific surface area, increased structural stability and greater numbers of exposed active sites. However, with further increases of LDH loading (Fig. 2e,f), the amount of LDH became excessive and accumulated on the surface of Mnt, and these could not support Mnt layers and gradually stacked together, revealing that excess LDH-modified Mnt still underwent aggregation and the accumulation of layers.

Figure 2. SEM images of (a,b) 1-LDH@Mnt, (c,d), 3-LDH@Mnt, (e,f) 5-LDH@Mnt and (g,h) Mnt.

Adsorption kinetics

The adsorption kinetics of ATZ and PQ by Mnt, LDH and composite samples over time were investigated, and the results are shown in Fig. 3. During the sorption process, the removal of ATZ and PQ was rapid in the first hour, and then the rate slowed down until adsorption equilibrium was established at 3 h. During the process of ATZ and PQ removal, the removal rate was one of the means used to evaluate adsorbent properties because it had a large effect on the removal efficiency and depended on the properties of the material. Therefore, we applied the quasi-first-order kinetic model (Equation 1), quasi-second-order kinetic model (Equation 2) and interdiffusion model (Equation 3) to analyse the experimental data. The average relative error (ARE) was utilized to assess the matching quality (Equation 4). A lesser ARE value indicates a better fitting degree.

(1)$$Q_t = Q_{\rm e}( {1-{\rm e}^{{-}t{\rm k}_1}} ) $$

(2)$$Q_t = \displaystyle{{Q_{\rm e}t} \over {( {1/{\rm k}_2Q_{\rm e}} ) {\rm \;} + {\rm \;}t}}$$

(3)$$Q_t = {\rm K}_it^{0.5} + C$$

(4)$${\rm ARE\ } = \displaystyle{{100} \over n}\mathop \sum \limits_i^n \left\vert {\displaystyle{{Q_{i, {\rm model\;}-{\rm \;}Q_{i, {\rm \;exp}}}} \over {Q_{i, {\rm exp}}}}} \right\vert $$

where Q _t and Q _e (mg g^–1) is the amount of adsorbed ATZ and PQ at time t and equilibrium, respectively. k₁ and k₂ (mL mg^–1 h^–1) represent the constants of the pseudo-first-order model and the pseudo-second-order model, respectively. K_i (mg g^–1 h^–1/2) represents the rate constant of internal diffusion and C is the coefficient of internal diffusion. Q _{i, model} is each Q (mg g^–1) value forecasted by the predicting model, Q _i,exp is each Q (mg g^–1) measured experimentally and n is the number of experimental points.

Figure 3. Kinetics of (a) ATZ and (b) PQ on Mnt, LDH, 1-LDH@Mnt, 2-LDH@Mnt, 3-LDH@Mnt, 4-LDH@Mnt and 5-LDH@Mnt fitted with pseudo-first-order, pseudo-second-order and internal diffusion models.

The fitted results of these models are displayed in Figs 3 & S3, and the calculated kinetic equation parameters are listed in Table 2. Based on the ARE and R ² values of the models, all of the samples showed better-fitting results to the adsorption testing data of ATZ and PQ according to the pseudo-second-order kinetic model. Additionally, the equilibrium removal values of ATZ and PQ, calculated using the pseudo-second-order model, closely matched the experimental data. The superior fit provided by the pseudo-second-order kinetic model suggests that the adsorption of ATZ and PQ is primarily governed by the number of adsorption sites on the adsorbent. Compared to Mnt and LDH, the adsorption capacities of compound adsorbents for ATZ and PQ were much larger, and 3-LDH@Mnt possessed the greatest removal efficiency. These results indicated that in composite adsorbents the mutually supported LDH and Mnt layers formed a porous structure and provided more accessible adsorption sites for ATZ and PQ removal. When the loading amount of LDH was small, the adsorption sites for ATZ and PQ were insufficient. However, overloading LDH on the Mnt surface resulted in excessive aggregation, which reduced the exposure of biosorption sites and lowered the adsorption amount. These variations in removal capabilities corresponded to changes in the shape of the composite adsorbents as well as increases in their specific surface area.

Table 2. Pseudo-first-order model and pseudo-second-order model kinetic parameters of ATZ and PQ adsorbed by Mnt, LDH, 1-LDH@Mnt, 2-LDH@Mnt, 3-LDH@Mnt, 4-LDH@Mnt and 5-LDH@Mnt.

The internal diffusion model was also used to analyse the test data, and the results of ATZ and PQ removal are shown in Fig. 3 and Table 3. From internal diffusion model results, at the beginning ATZ/PQ was first adsorbed on the surface of the adsorbent. Then, over time, ATZ/PQ molecules gradually diffused inside the adsorbent. Finally, adsorption equilibrium was reached. As a result, the adsorption process can be separated into three stages: surface diffusion, interdiffusion and adsorption equilibrium, demonstrating that interior biosorption sites are exposed and gradually become occupied during the sorption process. In composite sample, LDH and Mnt layers mutually supported each other to generate a pore structure, which led to more ATZ and PQ molecules diffusing into the interior of these samples and increased the diffusion rate of ATZ and PQ molecules during the adsorption process. The value of K_d2 represents the adsorption rate of internal diffusion, and sample 3-LDH@Mnt possessed the highest value of K_d2, revealing that this composite adsorbent has the most beneficial internal structure that is conducive to the removal of ATZ/PQ. Furthermore, from the linear fitting of intraparticle diffusion results we can see that not all samples’ fitted curves pass through the origin, indicating that the adsorption of ATZ and PQ molecules was controlled by multiple steps.

Table 3. Parameters of the internal diffusion model of ATZ and PQ adsorbed by Mnt, LDH, 1-LDH@Mnt, 2-LDH@Mnt, 3-LDH@Mnt, 4-LDH@Mnt and 5-LDH@Mnt.

Adsorption isotherms

The influence of the initial concentration on the removal of ATZ and PQ by Mnt, LDH and composite adsorbents was investigated. With increasing initial concentration, the adsorption amounts of ATZ and PQ for all samples increased initially, and then the adsorption amounts gradually reached equilibrium. To further analyse the mechanism of the removal process, Langmuir (Equation 5), Freundlich (Equation 6) and Henry (Equation 7) isotherm models were employed to fit the experimental data.

(5)$$\displaystyle{{C_{\rm e}} \over {Q_{\rm e}}} = \displaystyle{1 \over {{\rm K}_{\rm L}Q_{\rm m}}} + \displaystyle{{Q_{\rm e}} \over {Q_{\rm m}}}$$

(6)$$\log Q_{\rm e} = \log {\rm K}_{\rm F} + \displaystyle{1 \over n}\log C_{\rm e}$$

(7)$$Q_{\rm e} = {\rm K}_{\rm d}C_{\rm e}$$

where Q _m (mg g^–1) is the sorption capacity or adsorption maximum of ATZ and PQ onto adsorbents, Q _e (mg g^–1) is the equilibrium adsorption amount, K_L (L mg^–1) is the Langmuir coefficient (representing the adsorption affinity), K_F (mg^(1–n)/L^–n/g) is the Freundlich constant, n is the coefficient related to the adsorption intensity and K_d is the Henry coefficient.

The fitted curves and related parameters are shown in Fig. 4 and Table 4, respectively. For the removal of ATZ and PQ by all adsorbents, the Langmuir isotherm model showed a much higher correlation than the Freundlich model. Thus, the fitted results suggested that the adsorption of ATZ and PQ was primarily due to monolayer adsorption, and the adsorption could take place at a finite number of localized sites. R_L is the regular parameter of Langmuir and the formula to calculate this is R_L = 1/(1 + K_LC ₀), which reflects the essential characteristics of the Langmuir model. The calculated R_L values are shown in Table 4. The R_L results (0 < R_L < 1) revealed that composite adsorbents have a favourable adsorption affinity for ATZ and PQ. Furthermore, the sorption capacities of the various adsorbent were compared, and the results are presented in Table 5. The results revealed that, in comparison with other reported adsorbents, the 3-LDH@Mnt composite exhibited a superior adsorption capacity for ATZ and PQ.

Figure 4. Isotherm study of ATZ and PQ on Mnt, LDH, 1-LDH@Mnt, 2-LDH@Mnt, 3-LDH@Mnt, 4-LDH@Mnt and 5-LDH@Mnt fitted with (a,e) Langmuir, (b,f) Freundlich, (c,g) Henry and (d,h) generalized Langmuir models.

Table 4. Fitting parameters of the Freundlich, Langmuir and Henry models of Mnt, LDH, 1-LDH@Mnt, 2-LDH@Mnt, 3-LDH@Mnt, 4-LDH@Mnt and 5-LDH@Mnt for ATZ and PQ.

Table 5. Comparison of the adsorption capacities for ATZ and PQ of the various adsorbents.

Adsorption mechanism analysis

To delve deeper into the adsorption mechanism of PQ and ATZ, we characterized the 3-LDH@Mnt samples after adsorption, as depicted in Fig. 5. In the FTIR spectra results, after adsorption of PQ the symmetric and asymmetric stretching vibration peaks of C–H appeared at 2900 and 2780 cm^–1, and after sorption of ATZ the stretching vibration peak of C=N at 1500 cm^–1 was observed, indicating that PQ and ATZ were successfully adsorbed by the composite sample. The XRD traces of 3-LDH@Mnt after the adsorption of PQ and ATZ are shown in Fig. 5b. Compared with the XRD trace of 3-LDH@Mnt itself, after adsorption of PQ and ATZ no new peaks were produced, and the positions of the (003) peak did not shift, indicating that the adsorption of PQ and ATZ by LDH@Mnt was mainly via surface adsorption, and the contaminant did not enter the interlayers of the LDH and Mnt layers.

Figure 5. (a) FTIR spectra and (b) XRD traces after adsorption of ATZ and PQ on 3-LDH@Mnt.

Although the test data regarding ATZ and PQ removal using these samples could fit the Langmuir isothermal model well, some deficiencies in understanding the sorption process remained. The Langmuir model assumes adsorption on a single-layer surface in which all adsorption sites are identical and equivalent. In other words, each adsorption site possesses equal adsorption activation energy and there is no migration between adsorbed molecules. In the composite samples, both LDH and Mnt provide adsorption sites for ATZ or PQ, but these adsorption sites are not identical. This violates the hypothesis of the Langmuir model and fails to precisely describe the sorption process. The generalized Langmuir model, which evolved from the Langmuir model, is a generalized isothermal model that considers the non-uniformity of the adsorbent. Therefore, the generalized Langmuir model was used to analyse the removal process, and three more parameters of heterogeneity (m, n) and site adsorption energy (E) were introduced. Here, the generalized Langmuir model (Equation 8) can be written as follows:

(8)$$Q_{\rm e} = Q_{\rm g}^0 \left[{\displaystyle{{{( {{\rm b}_{\rm g}C_{\rm e}} ) }^m} \over {1{\rm \;} + {\rm \;}{( {{\rm b}_{\rm g}C_{\rm e}} ) }^m}}} \right]^{{n \over m}}$$

where $Q_{\rm g}^0$ is the maximum adsorption capacity, m and n are heterogeneity parameters and b is the adsorption energy-related Langmuir constant, which we defined to be <1. The fitted data and calculated correlation parameters are also shown in Fig. 4 and Table 6.

Table 6. Fitting parameters of the generalized Langmuir model of Mnt, LDH, 1-LDH@Mnt, 2-LDH@Mnt, 3-LDH@Mnt, 4-LDH@Mnt and 5-LDH@Mnt for ATZ and PQ.

The fitted results showed that, based on the correlation coefficient (R ²) and ARE results, the generalized Langmuir model provided a better fit of the data than the Langmuir model regarding the sorption of ATZ and PQ by the compound adsorbents, revealing that the generalized Langmuir model can better describe the removal process. Therefore, adsorption of ATZ or PQ molecules proceeded via monolayer adsorption, but the active sites of the composite adsorbents were inhomogeneous. To further investigate the differences between the adsorption-site distributions and active-site energies, we employed site energy distribution theory.

The non-uniform energy adsorption process of the adsorbent can be studied theoretically using site energy distribution theory. This enables the calculation of the distribution function and energy of biosorption sites, indicating the binding strength of the adsorbent and the adsorption site. The integral formula can be improved to forecast the power distribution of active sites in the theory of heterogeneous surface adsorption. It is considered that the adsorption capacity Qe(Ce) of the adsorbent on a non-uniform surface is equal to the integration of the adsorption isotherm Qh(E,Ce) multiplied by the energy distribution function F(E) of the local adsorption site with uniform energy (Equation 9).

(9)$$Q{\rm e}( {C{\rm e}} ) {\rm} = \mathop {\int} \limits _ 0 ^ \infty Q{\rm h}( {E{\rm , \;}C{\rm e}} ) {\rm F}( E ) {\rm d}E$$

In this context, the generalized Langmuir model is employed to investigate the site energy distribution during the adsorption process. The deduction process involved was presented in previous work (Xia et al., Reference Xia, Huang, Liang, Xie, Kong and Yang2022), and the formula yields the following results (Equations 10 & 11):

(10)$${\rm F}( {E^{\rm \ast }} ) {\rm} = \displaystyle{{nQ_{\rm g}^ 0 {( {{\rm b}_{\rm g}C_{\rm s}} ) }^n} \over {{\rm R}T}}{\rm exp}\left({\displaystyle{{{\rm - }nE^{\rm \ast }} \over {{\rm R}T}}} \right)[ { 1 + {( {{\rm b}_{\rm g}C_{\rm s}{\rm exp}( {{\rm - }E^{\rm \ast }{\rm /R}T} ) } ) }^m} ] ^{{\rm - }\left({{\rm 1 + }{n \over m}} \right)}$$

(11)$${\rm \mu }( {E^{\rm \ast }} ) {\rm} = \displaystyle{{{\rm R}T} \over m}{\rm ln}( { 1 + {\rm b}_{\rm g}{\rm C}_{\rm s}^m } ) $$

where E* is the difference in sorption energy between the adsorbent and the adsorbent at a certain sorption site, C _s is the maximum dissolubility of the sorbent in solution and R is the gas constant.

Figure 6a,b depicts the relationship between each sample's adsorption capacity and the site energy E* at the PQ and ATZ adsorption equilibrium point. The theory of site energy distribution explores the uneven adsorption energy process on the adsorbent from an energy perspective, revealing the power levels of the sorption sites and their distribution functions. The site energy (E*) of LDH, Mnt and LDH@Mnt composites dropped as the equilibrium adsorption capacity of ATZ and PQ increased, indicating that ATZ and PQ first selected the high-energy sites of the adsorbent in the initial stage of adsorption and preferentially occupied these high-energy sites. As the adsorption capacity increased, PQ/ATZ molecules occupied the low-energy sites on the adsorbents until all accessible locations were occupied. In the site energy distribution theory fitting results, the LDH@Mnt composite curve covered both high- and low-energy site regions, suggesting its ability to integrate the advantages of Mnt and LDH. This composite exposed additional adsorption sites through the mutual support of the LDH and Mnt layers, distinguishing it from Mnt and LDH alone. In Fig. 6a,b, the q _e–E* curves of the three composite samples show similar trends, and 3-LDH@Mnt possessed more adsorption sites, in accordance with the results from the structural and shape analysis.

Figure 6. The distributions and site energies for (a,c) ATZ and (b,d) PQ adsorption on Mnt, LDH, 1-LDH@Mnt, 3-LDH@Mnt and 5-LDH@Mnt.

The average site energies for the sorption of ATZ and PQ by Mnt, LDH and LDH@Mnt samples were also calculated, and the results are shown in Fig. 6c,d. LDH and Mnt have similar average site energies, which are 5.55 and 5.93 kJ mol^–1 for ATZ and 8.63 and 8.76 kJ mol^–1 for PQ, respectively. The calculated site energies of 1-LDH@Mnt, 3-LDH@Mnt and 5-LDH@Mnt are higher than those of LDH and Mnt, which were 7.46, 8.67 and 8.12 kJ mol^–1 for ATZ and 11.69, 14.47 and 9.72 kJ mol^–1 for PQ, respectively. The results demonstrate that the LDH@Mnt composite adsorbents possessed numerous adsorption sites and exhibited high adsorption energy, which are conducive to the removal of ATZ and PQ.

The effects of pH, coexistence of ions and reuse experiments

The impact of the initial pH on the adsorption effects of ATZ and PQ was investigated. The adsorption capacity of 3-LDH@Mnt for ATZ and PQ was determined at pH values ranging from 3 to 9, as shown in Fig. 7a,b. The sorption capacities for ATZ and PQ at pH 3 and 5 were much greater than those at pH 7 and 9, revealing that the adsorption effect under acidic conditions was better than that under neutral or basic conditions. Under acidic conditions, on account of the protonation reaction with ATZ/PQ molecules, ATZ/PQ in the form of cations was attracted to the negatively charged layers of Mnt and reduced the electrostatic repulsion with the LDH@Mnt composite, which was conducive to the removal of ATZ and PQ. However, under alkaline conditions, the concentration of H⁺ was decreased, and the protonation reaction of ATZ/PQ molecules was weakened, resulting in the adsorption amount for ATZ and PQ being decreased slightly.

Figure 7. Effect of (a,b) initial pH, (c–f) coexisting cations and anions and (g,h) reuse experiments on ATZ and PQ adsorption on 3-LDH@Mnt.

The effect of coexisting anions on the sorption of ATZ and PQ by 3-LDH@Mnt was also assessed, and the results are shown in Fig. 7c–f. The presence of Na⁺, K⁺, Mg²⁺ and Ca²⁺ cations and Cl^–, NO^3–, SO₄^2– and CO₃^2– anions did not exert much influence on the removal of ATZ and PQ, revealing that the LDH@Mnt composite possessed high adsorption stability and was reliable for the adsorption ATZ and PQ in various environmental systems. The reuse capability of 3-LDH@Mnt was also experimentally explored, and the results are shown in Fig. 7g,h. After five cycles, the adsorption amount was reduced to 6.32 mg g^–1 for ATZ and 70.8 mg g^–1 for PQ; however, the removal rates of ATZ and PQ still exceeded 70%, demonstrating the good reusability and continuous effective adsorption performance of the composite.