2.1. Synthesis of NaAZ via DES-assisted microwave hydrothermal method

A 3.0 M sodium hydroxide (NaOH, MERCK, 99.8%) solution was prepared using deionized water to provide the alkaline medium required for zeolite crystallization. Sodium meta-silicate (Na₂SiO₃, LOBA, 94%) was gradually added to the NaOH solution under continuous stirring until fully dissolved. Subsequently, aluminum sulfate (Al₂(SO₄)₃, LOBA, 99%) was introduced as the aluminum source, and the mixture was stirred thoroughly to ensure homogeneity. The resulting mixture developed into a gel-like consistency and was maintained under stirring for approximately 2 hrs to ensure complete dissolution and uniform distribution of the reactants. Na-A zeolite (NaAZ) was synthesized using a rapid, deep eutectic solvent (DES)-assisted microwave hydrothermal method. A DES was prepared by mixing choline chloride and urea in a 1:2 molar ratio under gentle heating until a clear, homogeneous liquid formed. Separately, sodium hydroxide (3.0 M) was dissolved in deionized water, followed by gradual addition of sodium metasilicate and aluminum sulfate under stirring to form a homogeneous precursor solution. The DES was then incorporated, and the resulting gel was stirred for 30 min to ensure uniformity. The mixture was transferred to a Teflon-lined microwave reactor and subjected to irradiation at 180 W and 80 °C for 45 min, enabling rapid nucleation and crystallization of NaAZ. The solid product was recovered by centrifugation, washed repeatedly with deionized water until neutral pH, and dried at 105 °C for 2–4 hrs [17]. All synthesis procedures were conducted at the Sanitary and Environmental Institute, Housing and Building National Research Center, Egypt.

2.2. Characterization of NaAZ

A combination of analytical techniques was employed to assess the structural, morphological, and chemical properties of the synthesized NaAZ. Surface area and pore characteristics were determined using the Brunauer–Emmett–Teller (BET) method with a Quantachrome analyzer (Quantachrome Instruments, USA). Infrared functional groups were examined using Fourier Transform Infrared Spectroscopy (FTIR) (Shimadzu FT-IR 8400S, Tokyo, Japan) within the wavenumber range of 400–4000 cm ⁻ ¹. Phase identification and crystallinity were analyzed by X-ray diffraction (XRD) using an XDS-2000 diffractometer equipped with Ni-filtered Cu Kα radiation. Surface morphology and particle shape were investigated using Scanning Electron Microscopy (SEM), while the elemental composition of the samples was evaluated through Energy Dispersive X-ray spectroscopy (EDX) using a QUANTAX system (Bruker, USA) attached to the SEM. Together, these techniques provided a comprehensive evaluation of the material’s framework structure, pore features, elemental composition, and adsorption-relevant morphology [17].

2.3. Chemicals and materials

Analytical-grade lead nitrate (Pb(NO₃)₂), copper sulfate pentahydrate (CuSO₄·5H₂O), cadmium nitrate tetrahydrate (Cd(NO₃)₂·4H₂O), nickel nitrate hexahydrate (Ni(NO₃)₂·6H₂O), and zinc nitrate hexahydrate (Zn(NO₃)₂·6H₂O) were purchased from Sigma–Aldrich (≥99% purity). Stock solutions (1000 mg/L) of each heavy metal were prepared using deionized water and subsequently diluted to the required concentrations [18].

2.4. Analytical determinations

The residual concentrations of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn²⁺ in the aqueous solution were determined using Atomic Absorption Spectroscopy (AAS, PerkinElmer Analyst 400) calibrated with external standards. Blanks and spiked recovery samples were included to ensure data accuracy. Perform blank experiments to check for metal loss due to container adsorption. Run adsorption tests in triplicate. Use procedural blanks and standard solutions to validate Atomic absorption performance [19].

2.5. Batch adsorption experiments

Batch adsorption studies were-performed to evaluate the removal of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions from aqueous solutions. Precisely weighed masses of NaAZ (0.010, 0.015, 0.020, 0.025, 0.030, 0.035, 0.040, 0.045, and 0.050 g) were-added separately to 100 mL of metal ion solution in 250 mL Erlenmeyer flasks. Initial concentrations of the metal ions (C₀) ranged from 0.5, 1.0, 1.5, 2.0, 2.5, 3.0, 3.5, 4.0, 4.5, and 5.0 mg/L.

The aqueous solution of samples were-incubated in a thermostatic orbital shaker at 25 ± 2 °C and 150 rpm for contact times of 10, 20, 30, 40, 50, 60, 90, 120, 150, and 180 min to determine adsorption kinetics and equilibrium behavior. At each time interval, samples were-withdrawn filtration through 0.45 µm cellulose nitrate membranes.

The effect of pH on the removal of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn²⁺ in the solution has been established and considered an important parameter affecting the performance of the adsorption process. At varied pH levels (3, 6, and 9), removing of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn²⁺ from the aqueous solution was conducted with a constant dosage of 0.025 g at 150 rpm/90 min, and 0.5 mg/L. Equilibrium thermodynamics (ΔG°, ΔH°, ΔS°), Temperatures: 15, 25, 35, 45 °C. Conditions: fixed adsorbent dose (0.025 g), pH (6.0), time (90) and C₀ (0.5 mg/L). t = t_eq at each T. Equations (1, 2) were using to compute distribution constant. Dimension less by using concentration units consistently or by dividing by standard state) [20].

(1)

(2)

Plot the ln K_c vs 1/T to extract ΔH° (slope) and ΔS° (intercept). 1/T to extract: ΔG° negative → spontaneous; ΔH° positive → endothermic; negative → exothermic.

2.6. Adsorption isotherm study

Equilibrium adsorption isotherms were-investigated by varying the initial concentrations of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions. For each experiment, 0.025 g of NaAZ was added to 100 mL of metal ion solution with initial concentrations (C₀) ranging from 0.5 mg/L. The suspensions were-incubated at 25 ± 2 °C on an orbital shaker 150 rpm for a contact time of 90 min, which was previously determined as sufficient to reach adsorption equilibrium. Equations (3, 4) were used to determine the amount of pollutants adsorbed at equilibrium (q_e) and the percentage removed (R %). Fit data to Langmuir, Freundlich, and Temkin, and models. Model fitting and parameter estimation were-performed by the coefficient of determination (R²) [21,22].

(3)

(4)

Where q_e (mg/g) represents the amount of pollutants adsorbed at equilibrium, V (L) is the volume of the solution, W (g) is the mass of the nanoparticles used, C_i, and C_e (mg/L) represents Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions concentrations at initial and equilibrium conditions, respectively.

2.6.1. Langmuir isotherm model.

Adsorption isotherms, which are typically the ratio between the amount adsorbed and that was left in solution at equilibrium at a specific temperature, are used to describe equilibrium studies that give the capacity of the adsorbent and adsorbate [21]. The Langmuir model is predicated on the hypothesis that maximal adsorption happens in the presence of a saturated monolayer of solute molecules on the adsorbent surface, the adsorption energy is constant, and there is no adsorbate molecule migration in the surface plane. The Langmuir isotherm model implies that physical factors drive monolayer sorption. The Langmuir isotherm is given by Equations (5–7):

(5)(6)(7)

where q_max and K are the Langmuir constants, where qe is the dose of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions adsorbed on a specific dose of adsorbent (mg/g), C_e is the equilibrium concentration of the solution (mg/L) and q_max is the maximum dose of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions concentration required to form a monolayer (mg/g). The values of q_m and K can be determined from the linear plot of C_e/q_e versus C_e [22]. R_L is separation factor calculated through Langmuir model.

2.6.2. Freundlich isotherm model.

The Freundlich isotherm model proposes that many sites with various adsorption energies are involved in the empirical relationship that describes the adsorption of solutes from a liquid to a solid surface. The system’s characteristics K_F and n are the indicators of the adsorption capacity and adsorption intensity, respectively. The Freundlich model’s capacity to match the experimental data was-investigated. The intercept value of K_F and the slope of n were-calculated for this scenario using the plot of log C_e vs. log q_e. The Freundlich isotherms appear when the surface is heterogeneous and the absorption is multilayered and bound to sites on the surface [22].. The Freundlich isotherm is-given by Equation (8):

(8)

where K is the Freundlich equilibrium constant (mg/g), 1/n = Intensity parameter C_e = Equilibrium concentration of adsorbate, q_e is the dose of solute adsorbed.

2.6.3. Temkin isotherm.

Equation (9) were used to determine the (adsorbate–adsorbent interactions and linear heat of adsorption):

(9)

Where B = RT/b, with R being the universal gas constant (8.314 J/mol.K), T the absolute temperature (K), b the Temkin constant related to the heat of adsorption (J/mol), and K_T (L/mg) the Temkin isotherm constant [21,22].

2.7. Adsorption Kinetic Study

Kinetic experiments were-conducted to investigate the adsorption rate and mechanism of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions onto NaAZ. For each test, known masses of NaAZ (0.025 g) were added to 100 mL of metal ion solutions with initial concentrations (C₀ 0.5 mg/L). The suspensions were agitated in an orbital shaker at 25 ± 2 °C and 150 rpm. Samples were-withdrawn at predetermined time intervals (10, 20, 30, 40, 50, 60, 90, 120, 150, and 180 min) to monitor the adsorption process. The adsorption capacity at time t (qt, mg/g) was calculated using Equation (2). It was possible to characterize the kinetics for each adsorbent, using pseudo-first, pseudo-second-order kinetic models, and and Intraparticle diffusion model (Weber–Morris).The pseudo-first-order kinetics follows the Lagergren model expressed by Equation (10):

(10)

where q_t is the adsorbed dose of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions (mg/g) in t time (min) and k₁ is the pseudo-first-order constant (min^-1).

Through linear and angular constant of log graphic (q_eq – q_t) in the function of time, q_eq and k₁ can be calculated, respectively. Comparing the experimentally obtained values for q_eq calculated by pseudo- second-order kinetics by Equation (11):

(11)

where k₂ is the pseudo-second-order constant (g/mg. min) obtained by calculation of linear coefficient and q_eq is calculated through angular coefficient [23].

To evaluating the goodness of fit for non-linear kinetic models (pseudo-first-order, and pseudo-second) in adsorption and biodegradation processes, error analysis is essential such as sum of Squared Errors (SSE). Equation (12) [24].

(12)

Where q_{e, exp}, is the experimental adsorption capacity and q_e, _calc is the calculated value from the model. Lower SSE values indicate a better fit of the model to the experimental data, and highly sensitive to large deviations.

The experimentally obtained values for q_eq calculated by Intraparticle diffusion model by Equation (13):

(13)

where k_id (mg/g·min ⁻ ¹/²) is the intraparticle diffusion rate constant and C (mg/g) represents the boundary layer effect.

2.8 Fixed-bed column tests

Fixed-bed column experiments were-performed to evaluate the dynamic performance of NaAZ for simultaneous removal of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni²⁺ and Zn² ⁺ .

2.8.1. Column packing and operating conditions.

A glass column (internal diameter = 10 mm, i.d. = 1.0 cm) was wet-packed with NaAZ to a bed height (L) of 10.0 cm. Prior to testing, the packed bed was conditioned with deionized water until the effluent conductivity matched the influent. The feed solution consisted of an equimolar mixture of the five metal ions at C₀ = 5.0 mg/L each. The feed was introduced to the column in down flow mode at a constant volumetric flow rate Q = 2.6 mL/min using a peristaltic pump. All tests were-performed at ambient laboratory temperature (≈25 °C). Effluent samples were collected at regular time intervals (Hussein et al 2022) [25]. (Table 1) show Column geometric parameters. Effluent was-sampled at fixed intervals (2–5 min). The concentration ratio C_t/C₀ was plotted versus time to generate breakthrough curves. Breakthrough time (b_t) was defined at C_t/C₀ = 0.10 (10% of influent) and full breakthrough at C_t/C₀ = 0.90.

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Table 1. Column geometric parameters.

https://doi.org/10.1371/journal.pone.0341007.t001

2.8.2. Bohart-Adams model.

The nonlinear form of Bohart-Adams models is shown in Equation (14). In fixed-bed column, it is employed to determine the initial condition of the surface operation. The model is based on the surface reaction theory. The adsorption rate is considered to be proportional to both the residual adsorbent capacity and the initial concentration of the adsorbed.

(14)

Where, 𝛼 = 𝑘_𝐵𝐴*𝑁_𝑜*𝑍, 𝛽 = 𝑘_𝐵𝐴 * 𝐶_𝑜 * 𝑡. K_BA signifies the Bohart-Adams kinetic constant (L/mg. min). 𝑁_𝑜 and Z is the saturation concentration (mg/L) as well as the bed depth of the column (cm), respectively [26,27].

2.8.3. Yoon-Nelson model.

It is used to describe the time of column run before the replacement of column or regeneration became mandatory. Yoon-Nelson model assumes that, the rate of decrease in the probability of adsorption for each adsorbate molecule is proportional to the probability of adsorbate adsorption and the probability of adsorbate breakthrough on the adsorbent. The nonlinear form of the model is given in Equation (15). The Yoon-Nelson model is a descriptive model that uses experimental data to calculate parameters that are then entered into the model [26,27].

(15)

t = breakthrough time (min), t = 50% contaminant breakthrough time (min)

k’ = rate constant (min^-1)

C_I = contaminant assault concentration mg/L

2.8.4. Thomas model.

Thomas model is widely used to describe the column performance and to predict the breakthrough curves. The nonlinear form of the model is represented in Equation (16) [26,27].

(16)

𝑘_𝑇ℎ represents the Thomas constant in (mL/min.mg), 𝑞_𝑇ℎ denotes the uptake capacity calculated by the Thomas model in (mg/g), m denotes the adsorbent mass in the column in (g), and Q represents the volume flow rate in (mL/min).

2.9. Regeneration and reusability studies of NaAZ for removal of heavy metal

Regeneration of NaAZ is essential to restore its adsorption capacity after saturation and to enable repeated use in wastewater treatment. Reusability not only improves cost-effectiveness but also enhances the sustainability of the treatment process. Previous investigations have shown that regenerated NaAZ can efficiently remove heavy metal ions such as Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn²⁺ across multiple adsorption cycles. During operation, NaAZ gradually becomes saturated with adsorbed ions, leading to diminished removal efficiency. Regeneration reverses this process by desorbing the retained ions and restoring active exchange sites. Among the available techniques, both chemical and thermal regeneration are commonly applied. Thermal regeneration (calcination) involves heating the exhausted material to around 600 °C to decompose and remove adsorbed organic matter. Although this method can achieve near-complete regeneration and is effective for organics and volatile contaminants, it is energy-intensive and less practical for large-scale use dominated by inorganic pollutants. Chemical regeneration is more suitable for heavy metal-loaded zeolite. In this approach, the exhausted NaAZ is treated with an acid solution—typically hydrochloric acid (HCl, 1.0 N) which replaces the retained metal ions with sodium or hydrogen ions. Following regeneration, the material is thoroughly washed with deionized water to remove excess acid and prevent secondary contamination.

In this study, NaAZ was subjected to five consecutive adsorptions–desorption cycles to assess its regeneration potential. After each cycle of heavy metal adsorption, the material or column bed was flushed with 1.0 N HCl to restore ion-exchange capacity. The regenerated zeolite was then reused under the same experimental conditions. The multi-cycle evaluation allowed the determination of adsorption capacity retention, efficiency loss, and structural stability over repeated use. These findings are critical for evaluating the economic feasibility of NaAZ in real wastewater treatment applications and determining its long-term performance under operational conditions. we have described the equipment used for the adsorption–desorption cycles, including the regeneration vessel, temperature control system, agitation conditions, and the procedure for monitoring each regeneration cycle

3.1. Characterization of NaAZ

3.1.1. Physical properties and BET analysis of NaAZ.

The NaAZ due to its aluminosilicate framework and sodium-rich composition, exhibits high cation-exchange capacity and notable ionic mobility. These characteristics make it suitable for applications such as ion exchange, adsorption, gas separation, water treatment, desiccation, and detergent formulation. To examine its textural features, nitrogen adsorption–desorption measurements were performed using the BET method. The results confirmed that the material contains a uniform microporous network with a considerable specific surface area and well-defined pore architecture. These structural traits enable efficient interaction with dissolved species, offering multiple accessible active sites for adsorption. The presence of interconnected pores and a large surface-to-volume ratio enhances the material’s ability to capture contaminants including metal ions, ammonium, and various organic pollutants, as illustrated in Fig 1 and summarized in Table 2. The BET-derived values for surface area and pore volume provide useful indicators of the adsorbent’s functionality, accessibility of internal channels, and overall suitability for water purification and related environmental applications [28].

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Table 2. Physical properties and BET analysis of NaAZ.

https://doi.org/10.1371/journal.pone.0341007.t002

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Fig 1. BET analysis of NaAZ.

https://doi.org/10.1371/journal.pone.0341007.g001

3.1.2. X-Ray diffraction (XRD).

The X-ray diffraction (XRD) profile of the synthesized NaAZ, illustrated in Fig 2, displays prominent reflections at 2θ values of 10.22°, 21.74°, 27.08°, 30.16°, and 40.88°. These peaks correspond to the (100), (200), (321), (400), and (420) crystallographic planes, which are characteristic of the LTA zeolite structure. The intensity and sharpness of the peaks, combined with the minimal amorphous background signal, demonstrate that the material is well crystallized and of high phase purity [29]. The diffraction pattern confirms that NaAZ is the dominant crystalline phase. However, very weak signals attributable to hydroxysodalite were detected when higher NaOH concentrations (3.0 N) were used during synthesis. This observation agrees with previous investigations, which noted that elevated alkalinity can promote hydroxysodalite formation at the expense of pure LTA phases.

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Fig 2. X. ray diffraction patterns of NaAZ.

https://doi.org/10.1371/journal.pone.0341007.g002

Elemental composition determined by X-ray fluorescence (XRF) is summarized in Table 3. The primary constituents were silicon (≈65 wt%), aluminum (≈17.5 wt%), and sodium (≈6.5 wt%), matching the stoichiometry typically reported for NaAZ based on its aluminosilicate network. The calculated SiO₂/Al₂O₃ ratio was approximately 3.7, which is consistent with the range reported in earlier studies, including the work of Zhang et al. (2019) [30]. We now explicitly state the NaOH concentration used in the optimized synthesis of the novel NaAZ. The final synthesis was carried out using 2.0 N NaOH, a condition under which no detectable hydroxysodalite peaks were observed in the XRD profile. As noted, hydroxysodalite formation occurred only when higher alkalinity (3.0 N NaOH) was tested during preliminary trials; however, this condition was not employed in the final synthesis reported in this study. We have clarified in the text that the optimized 2.0 N NaOH condition yielded phase-pure, highly crystalline LTA-type NaAZ with no measurable hydroxysodalite impurities. Accordingly, the adsorption results reported in the manuscript represent the performance of pure NaAZ, free from secondary phases. In addition, we added a brief discussion of the potential implications of hydroxysodalite formation. Although the impurity appeared only under non-optimized conditions, we now note that hydroxysodalite typically possesses lower surface area and reduced pore accessibility compared to LTA zeolite.

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Table 3. Chemical composition of the NaAZ.

https://doi.org/10.1371/journal.pone.0341007.t003

3.1.3. Scanning electron microscopy (SEM).

Fig 3 presents the SEM micrographs of the synthesized NaAZ, which clearly display well-defined, uniformly distributed cubic crystals with sharp edges. The average particle size is observed to be below 70 µm. The images also show aggregates of partially reacted meta-kaolinite plates interspersed with discrete NaAZ cubic particles, confirming the successful conversion of the precursor material into the zeolitic phase. The SEM observations provide critical insight into the surface morphology, particle size distribution, and textural features of the synthesized material—factors that significantly influence adsorption performance. Smaller crystal dimensions are generally associated with increased external surface area, which facilitates enhanced adsorption capacity and faster uptake of solutes. High-resolution SEM further reveals cubical particles ranging from 1 µm to 3 µm in size, consistent with the typical morphology of NaAZ reported by Cheng et al. (2018) [31]. The observed uniformity in particle size supports stable and predictable adsorption behavior and improves handling characteristics in potential industrial applications. Complementary BET surface analysis confirmed the coexistence of both micropores and mesopores, indicating that the adopted synthesis approach successfully produced hierarchical porosity without compromising the intrinsic microporous framework of NaAZ. This observation aligns with findings by Wang et al. (2020) [32]. The presence of mesopores is particularly advantageous, as it enhances intra-particle diffusion, increases accessibility to active sites, and contributes to the improved adsorption kinetics recorded for the synthesized zeolite.

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Fig 3. SEM micrographs of NaAZ.

https://doi.org/10.1371/journal.pone.0341007.g003

3.1.4. Energy dispersive X-ray spectroscopy (EDX).

The EDX spectroscopy was performed to verify the elemental composition of the synthesized NaAZ and to confirm the successful formation of the aluminosilicate framework. The EDX spectrum Fig 4 clearly demonstrates the presence of sodium (Na), aluminum (Al), silicon (Si), and oxygen (O), which are the key constituents of NaAZ. The measured elemental distribution aligns closely with the theoretical stoichiometry expected for NaAZ, validating the structural integrity and successful synthesis of the material. Quantitatively, the NaAZ sample was found to contain approximately 29.19 wt% oxygen, 5.48 wt% silicon, 5.83 wt% aluminum, and 4.34 wt% sodium. These values correspond well with the characteristic composition of Na-A zeolite and reflect an appropriate Si/Al ratio, which is critical for determining ion-exchange capacity and adsorption behavior. Zeolitic materials typically comprise a framework of tetrahedrally coordinated aluminum and silicon linked by oxygen atoms, with charge-balancing cations such as sodium residing within the pore structure. In some cases, other cations such as titanium, tin, or zinc may substitute or coexist depending on the synthesis conditions and precursor composition [33]. The absence of extraneous elements in the spectrum further suggests high material purity and the effective transformation of the starting material into the target zeolitic phase.

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Fig 4. EDX and percentage constituents of NaAZ.

https://doi.org/10.1371/journal.pone.0341007.g004

3.1.5. Fourier transform infrared spectroscopy (FT-IR).

FTIR spectroscopy was conducted to verify the functional groups and vibrational modes associated with the aluminosilicate framework of the synthesized NaAZ. The spectrum Fig 5 displays key absorption bands at 3421, 1166, and 1080 cm ⁻ ¹, which are characteristic of Si–O and Al–O stretching vibrations within the zeolitic lattice. The broad band centered around 3421 cm ⁻ ¹ corresponds to O–H stretching from surface hydroxyl groups and physisorbed water, suggesting the retention of moisture within the pore channels. A strong absorption peak at 1080 cm ⁻ ¹ is associated with Si–O stretching and reflects contributions from the meta-kaolinite precursor. Notably, the disappearance of the band typically observed near 530 cm ⁻ ¹, attributed to Al[O(OH)]₆ bending, confirms the dehydroxylation of kaolinite during calcination and its subsequent structural reorganization into the zeolite framework [34,35]. Residual water-related bands are attributed to van der Waals interactions between hydroxyl groups and the electrostatic field generated by Na⁺ cations within the structure [36]. Additionally, the breathing mode of the double six-ring (D6R) units, reported to occur near 530 cm ⁻ ¹ in LTA-type zeolites [36,37], provides further evidence of the successful formation of the target topology. Overall, the FT-IR results verify the development of a well-defined aluminosilicate framework with high structural order and purity, consistent with the excellent adsorption characteristics reported for NaAZ materials [38].

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Fig 5. FT-IR for the NaAZ.

https://doi.org/10.1371/journal.pone.0341007.g005

3.2. Effect of contact time

The adsorption kinetics of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn²⁺ onto the hierarchical NaAZ displayed a characteristic two-stage behavior. An initial rapid uptake occurred within the first 30–60 min, followed by a slower adsorption phase that gradually approached equilibrium. The equilibrium times were approximately 120 min for Pb² ⁺ & Cu²⁺ and about 150 min for Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ . This biphasic pattern is typical for ion-exchange adsorbents, where the early rapid stage corresponds to the occupation of abundant as shown in Fig 6, readily accessible exchangeable Na⁺ sites on the external surface of the zeolite particles [39]. The slower phase is dominated by intra-particles diffusion, involving transport of metal ions into micro-pores and meso-pores within the zeolite framework [40]. The hierarchical structure synthesized in this study, featuring enhanced meso-porosity and improved pore connectivity, significantly accelerated the adsorption process, reducing equilibrium times. This improvement is attributed to the facilitated diffusion pathways provided by meso-pores, which reduce internal mass transfer resistance and enable faster access of metal ions to internal adsorption sites [41]. Enhanced mass transfer kinetics contribute to more efficient heavy metal removal, particularly important for practical applications where shorter treatment times are desirable [42]. Dual-modification strategies have been used to enhance stability and charge behavior in zinc-ion systems Zhang, M. et al (2025) [43].

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Fig 6. A adsorption capacity (qₜ, mg/g) vs. time (min).

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3.3. Effect of adsorbent dose

The removal efficiency of Pb²⁺ and Cu² ⁺ ions increased consistently with increasing adsorbent dose, ranging from 100 mg to 500 mg, achieving over 95% removal at the highest dose of 500 mg as shown in Fig 7. This trend is attributed to the increased availability of active adsorption sites with higher amounts of zeolite, which enhances the likelihood of metal ion capture from solution [44]. However, despite this increase in removal efficiency, the adsorption capacity (q_e, mg/g) decreased at higher adsorbent doses. This decrease can be explained by the presence of unsaturated binding sites when excessive adsorbent is added, leading to inefficient utilization of the adsorbent surface [38]. Additionally, partial aggregation of adsorbent particles at higher doses can reduce the effective surface area accessible to metal ions, further limiting adsorption capacity per unit mass. An optimal adsorbent dose of 250 mg was identified as a balance between maximizing removal efficiency and ensuring effective adsorbent utilization. Selecting this dose avoids excessive material use and minimizes issues related to particle aggregation while maintaining high adsorption performance [42].

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Fig 7. A adsorption capacity (qₜ, mg/g) vs. dose(g).

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3.4. Effect of initial concentration

At a fixed adsorbent dose and contact time (250 mg 120 min), the adsorption capacity (qₑ) of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Zn² ⁺ , and Ni² ⁺ increased with rising initial metal ion concentration (C_₀) as shown in Fig 8. This behavior is typical in adsorption processes, where higher concentrations provide a greater driving force for mass transfer, leading to enhanced loading of adsorbate on available adsorption sites [44]. However, the removal efficiency (R %) exhibited a decreasing trend at higher C_₀ values, which can be attributed to the saturation of adsorption sites. As these sites become fully occupied, the proportion of metal ions removed relative to the initial amount declines, despite the increase in absolute uptake capacity. Isotherm analysis further clarified the affinity sequence for these metal ions on the hierarchical NaAZ, Pb²⁺ > Cu²⁺ > Cd²⁺ > Zn²⁺ > Ni² ⁺ . This order is consistent with their hydrated ionic radii and established ion-exchange selectivity of NaAZ frameworks, where smaller or less hydrated ions tend to have lower affinity due to weaker electrostatic interactions [41]. Pb²⁺ and Cu² ⁺ , possessing favorable ionic sizes and hydration characteristics, exhibited the strongest affinity, which corresponds well with their higher maximum adsorption capacities reported in this study.

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Fig 8. A adsorption capacity (qₜ, mg/g) vs. initial concentration mg/L.

https://doi.org/10.1371/journal.pone.0341007.g008

3.5. Effect of pH

The pH is the most critical parameter affecting any adsorption studies due to their interference in the solid–solution interface, affecting the charges of the active sites of the adsorbents and the Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ behavior in the solution. The adsorption of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn²⁺ onto hierarchical NaAZ was found to be highly pH-dependent. At low pH values (3–4) as shown in Fig 9, the adsorption capacity was significantly reduced due to the competitive adsorption between abundant protons (H⁺) and metal ions for the negatively charged sites on the zeolite surface. This proton competition effectively inhibits metal ion uptake, consistent with previous studies on ion-exchange materials [44]. The optimal adsorption occurred in the pH range of 5.5–6.5, which coincides with the predominant presence of free divalent metal cations in solution and a negatively charged zeolite surface. Under these conditions, ion exchange between Na⁺ ions and metal ions is facilitated, leading to maximum adsorption efficiency [42]. The negative surface charge enhances electrostatic attraction, promoting stronger interactions with metal cations. Above pH 7, a slight decrease in dissolved metal concentrations was observed, likely due to the onset of metal hydroxide precipitation rather than true adsorption. This was confirmed through control experiments without adsorbent, which showed similar reductions in metal concentration, indicating precipitation rather than adsorption [40]. Therefore, pH values above 7 are not optimal for adsorption studies of these metals as precipitation can interfere with adsorption measurements. Overall, the optimal pH window of 5.5–6.0 balances the availability of free metal ions and the surface charge characteristics of the zeolite, maximizing ion-exchange efficiency and removal capacity.

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Fig 9. A adsorption capacity (qₜ, mg/g) vs. pH values.

https://doi.org/10.1371/journal.pone.0341007.g009

3.6. Effect of temperature

The adsorption capacity of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Zn² ⁺ , and Ni²⁺ on hierarchical NaAZ increased with rising temperature (15–45 °C), as shown in Fig 10, indicating that the process is endothermic. Higher temperatures provide the energy needed to overcome activation barriers associated with chemisorption and enhance ion mobility within the porous structure, promoting stronger interactions between metal ions and the zeolite framework [44].

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Fig 10. A adsorption capacity (qₜ, mg/g) vs. T ^oC.

https://doi.org/10.1371/journal.pone.0341007.g010

Thermodynamic analysis further supports this conclusion. The negative Gibbs free energy values (ΔG° = −10 to −20 kJ·mol ⁻ ¹) confirm that adsorption is spontaneous under the studied conditions, with larger negativity at higher temperatures reflecting increasingly favorable uptake [45]. Positive enthalpy changes (ΔH° = 20–35 kJ·mol ⁻ ¹) corroborate the endothermic nature of the process and indicate that chemisorption—including ion exchange or surface complexation—dominates over physical adsorption mechanisms [41]. Importantly, the positive entropy changes (ΔS°) reflect increased randomness at the solid–solution interface. This is primarily due to the partial release of structured water molecules from the hydration shells of metal ions as they bind to active sites on the zeolite surface. The resulting increase in disorder contributes favorably to the overall thermodynamic driving force, reinforcing the spontaneity of the adsorption process and highlighting the dynamic nature of the interface during ion exchange. Together, these thermodynamic parameters confirm that the hierarchical NaAZ facilitates spontaneous, endothermic chemisorption accompanied by increased system disorder, enhancing the efficiency of heavy-metal removal.

3.7. Isotherm studies

Fig 11 and Table 4 present the equilibrium adsorption data for Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Zn² ⁺ , and Ni² ⁺ ions onto the hierarchical NaAZ. The results show that the Langmuir isotherm model provides the best fit for all metal ions, with correlation coefficients R² > 0.98. This excellent agreement indicates monolayer adsorption on homogeneous active sites, where each ion occupies a discrete adsorption site without interaction with neighboring species. The Langmuir parameters revealed a clear capacity trend of Pb²⁺ > Cu²⁺ > Cd²⁺ > Zn²⁺ > Ni² ⁺ , consistent with ion-exchange–dominated monolayer adsorption. The superior adsorption performance and distinct selectivity pattern of NaAZ stem from the combined effects of hierarchical porosity and defect-engineered active sites rather than simple ionic size or hydration radius considerations. The DES-assisted microwave synthesis promotes the formation of interconnected micro–mesoporous channels, which enhances ion diffusion and facilitates rapid access to the internal LTA cages. This structural hierarchy particularly benefits larger and more polarizable ions such as Pb² ⁺ , enabling deeper penetration and more efficient utilization of internal adsorption sites. that equilibrium was reached after 120 min. Additionally, the controlled incorporation of framework defects—such as oxygen-rich coordination sites (Si–O⁻ and Al–O⁻), hydroxyl bridges, and charge-compensating Na⁺ centers—creates highly reactive Lewis basic sites capable of forming strong inner-sphere complexes. Pb² ⁺ , being softer and more polarizable, shows the highest affinity for these defect sites, resulting in the highest q_max. Cu² ⁺ follows due to its ability to form stable surface complexes and partially dehydrate at the interface. In contrast, Zn²⁺ and Ni² ⁺ exhibit weaker interaction due to their higher charge density and stronger hydration shells, which limit dehydration and penetration into the LTA pores.

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Table 4. The isotherm adsorption parameters for the studied metal ions adsorbed on NaAZ.

https://doi.org/10.1371/journal.pone.0341007.t004

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Fig 11. Langmuir, Temkin and Freundlich isotherm models for metal ions on NaAZ.

https://doi.org/10.1371/journal.pone.0341007.g011

Although the Freundlich constants (n < 1.0) indicate non-favorable adsorption on heterogeneous sites, the superior fit of the Langmuir model confirms that monolayer ion exchange is the dominant mechanism. Overall, these findings demonstrate that the hierarchical NaAZ synthesized in this study exhibits excellent adsorption capacities, well-defined selectivity, and strong potential for heavy-metal remediation applications [44,45].

3.8. Kinetic studies

The kinetic behavior of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ adsorption onto the hierarchical NaAZ was analyzed using the pseudo-first-order, pseudo-second-order, and intra-particle diffusion models. As presented in Fig. 12 and Table 5, the pseudo-first-order model produced relatively low correlation coefficients (R² = 0.8302–0.9081), indicating that it does not adequately describe the adsorption kinetics. In contrast, the pseudo-second-order model yielded markedly higher R² values (0.9335–0.9676) along with consistent rate constants (K₂ = 1.84 × 10 ⁻ ⁵–1.56 × 10 ⁻ ⁴ g mg ⁻ ¹ min ⁻ ¹), confirming that this model best represents the experimental data. The strong agreement with the pseudo-second-order model indicates that chemisorption—through electron sharing or exchange between framework Na⁺ ions and divalent metal cations—is the dominant rate-controlling mechanism [44].

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Table 5. The adsorption kinetic models parameters regarding the of metals ions adsorbed on NaAZ.

https://doi.org/10.1371/journal.pone.0341007.t005

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Fig 12. Kinetic models for metal ion adsorbed on NaAZ.

https://doi.org/10.1371/journal.pone.0341007.g012

The adsorption process proceeds through a characteristic two-stage pathway. The initial rapid uptake within the first 30–60 minutes is attributed to surface adsorption onto abundant, easily accessible exchange sites. This is followed by a slower stage in which metal ions diffuse into the micro- and mesoporous regions of the zeolite. Such sequential behavior is typical for porous adsorbents and highlights the critical role of pore architecture in influencing adsorption kinetics [45].

Further examination using the intra-particle diffusion (Weber–Morris) model resulted in lower R² values (0.8099–0.9076) and non-zero intercepts, demonstrating that intra-particle diffusion contributes to, but does not solely control, the overall adsorption process. The diffusion rate constants (K_id = 1.37–1.957 mg g ⁻ ¹ min ⁻ ⁰·⁵) support the presence of a two-step mechanism: rapid surface adsorption followed by slower diffusion into the hierarchical micro–mesoporous network. The enhanced porosity generated through DES-assisted synthesis significantly improves mass transfer compared to conventional microporous NaA zeolites, enabling faster adsorption kinetics [42]. This structural advantage is especially important for practical water treatment applications where rapid removal of heavy metals is required [46–47].

In summary, the kinetic and diffusion analyses highlight the combined effects of chemisorption and improved pore accessibility in achieving the superior adsorption performance of the hierarchical NaA zeolite toward divalent heavy metals [48–50].

3.9. Fixed-bed column studies

Dynamic adsorption studies based on the DD were conducted to evaluate the effect of the pre-selected three independent variables on the adsorption capacity of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Zn² ⁺ , and Ni² ⁺ adsorption onto NaAZ. The Fixed-bed length (3, 5, 15) cm, effluent Flow rate (Q) (2 mL min⁻¹) and initial concentration of metal (1, 5, 10) mg/L were chosen as the independent variables. The combined effect of bed height (3, 5, 15) cm and initial concentration (1, 5, 10) mg/L on the adsorption capacity of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Zn² ⁺ , and Ni²⁺ at a volumetric constant Flow rate (2 mL min⁻¹) are shown in Table 6. The response function (the adsorption capacity of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Zn² ⁺ , and Ni² ⁺ increased with an increasing initial concentration of ions as well as the bed height. This trend could be explained by the fact that increasing the bed height results in an increased availability of active sites for adsorption and a higher influent concentration provides a higher driving force for transfer to overcome mass-transfer resistance. The Fig 13 show relation between C_e/C_i against to fixed bed length (cm), The breakthrough curves from the fixed-bed column experiments exhibited notably steeper fronts for Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Zn² ⁺ , and Ni² ⁺ adsorption onto NaAZ indicating their higher affinity and faster adsorption kinetics. This behavior aligns with their higher ion-exchange selectivity and smaller hydrated ionic radii, which facilitate quicker diffusion and stronger interaction with the NaAZ adsorption sites [42]. The estimated mass transfer zone (MTZ) length of approximately 3, 5, 15 cm indicates efficient utilization of the adsorbent bed, suggesting that the hierarchical pore structure of the NaAZ enhances intra-particle diffusion and reduces resistance to mass transfer. Such structural advantages contribute to shorter equilibrium times and improved dynamic capacities compared to conventional zeolites [45]. Collectively, these findings demonstrate the superior performance of hierarchical NaAZ for continuous-flow heavy metal removal. The combination of high affinity for Pb²⁺ and Cu² ⁺ , favorable kinetic behavior, and efficient bed utilization highlights its practical potential for industrial wastewater treatment applications [51–53].

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Table 6. Experimental data in the DD for removal of metals ions.

https://doi.org/10.1371/journal.pone.0341007.t006

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Fig 13. Fixed-bed column studies for metal ion adsorbed on NaAZ.

https://doi.org/10.1371/journal.pone.0341007.g013

3.10. Mathematical modeling of breakthrough curves

Removal of inorganic and organic matters from wastewater was performed by fixed bed adsorption. To study the performance of fixed bed column for phenol removal by adsorption process, eight analytical models were validated. Breakthrough curves were calculated for Bed Depth Service Time, Thomas, Yoon–Nelson, and Bohart–Adams equations as shown in Fig 14–16. the data obtained revealed that the experimental data fits and respond well to each correlation coefficient values as shown in Table 7, the Bohart–Adams model demonstrated the best correlation with the experimental data, exhibiting an R² value is 0.9787, 0.9889, 0.9917, 0.9989, and 0.9927, for Pb, Cu, Cd, Ni, and Zn respectively [54–56]. This excellent agreement indicates that the Bohart–Adams model accurately describes the adsorption kinetics and breakthrough characteristics of fixed-bed column [57,58].

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Table 7. The mathematical modeling parameters regarding the of metals ions adsorbed on NaAZ.

https://doi.org/10.1371/journal.pone.0341007.t007

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Fig 14. Thomas models breakthrough curves for phenol adsorption.

https://doi.org/10.1371/journal.pone.0341007.g014

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Fig 15. Yoon–Nelson models breakthrough curves for phenol adsorption.

https://doi.org/10.1371/journal.pone.0341007.g015

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Fig 16. Bohart-Adams models breakthrough curves for phenol adsorption.

https://doi.org/10.1371/journal.pone.0341007.g016

3.11. Regeneration and reusability

The hierarchical NaAZ exhibited excellent regeneration performance, (Fig 17) showing the five consecutive adsorption–desorption cycles as the re-generation process (360, 340, 280, 232, and 268) mg/g for Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions, respectively. after These results demonstrate the potential of the synthesized zeolite for cost-effective and sustainable application in continuous heavy metal removal processes. The regeneration and reusability results demonstrate that the hierarchical NaAZ possesses excellent stability and sustained adsorption performance for the removal of Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions over multiple adsorption–desorption cycles. After five consecutive cycles, the zeolite retained high efficiency for removal for all metals, with 90%, 85%, 70%, 58%, and 67% for Pb² ⁺ , Cu² ⁺ , Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ ions, respectively. This indicates strong binding affinity and efficient desorption using 0.1 M HCl as the re-generator. The slight decrease in adsorption capacity across cycles can be attributed primarily to incomplete desorption of the metal ions and possible minor fouling or pore blockage, consistent with previous studies on zeolite regeneration [44]. Notably, the retention trend across metals correlates well with their initial adsorption capacities and affinities Pb²⁺ and Cu² ⁺ maintain higher capacities due to their stronger ion-exchange interactions and smaller hydrated ionic radii [42]. Cd² ⁺ , Ni² ⁺ , and Zn² ⁺ exhibit slightly lower retention, potentially because of their comparatively weaker interactions with the zeolite surface. The practical implication of th/ese findings is significant, the NaAZ synthesized via the hierarchical method offers a robust adsorbent suitable for repeated use in real wastewater treatment systems, reducing operational costs associated with adsorbent replacement. Furthermore, the effective regeneration with a relatively mild regenerate (HCl) demonstrates an environmentally friendly approach to adsorbent reuse [45]. Overall, the balance between high initial adsorption capacity, strong affinity for heavy metals, and excellent regeneration performance confirms the potential of this hierarchical NaAZ as a promising material for sustainable and cost-effective heavy metal remediation.

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Fig 17. Regeneration study for metal ion adsorbed on NaAZ.

https://doi.org/10.1371/journal.pone.0341007.g017

3.12. Comparison of NaAZ with other adsorbents for heavy-metal removal

Table 8, show the qₘₐₓ values (Langmuir qₘₐₓ) for many studies using different materials, Conditions (pH, T) vary between studies—compare carefully. Replace “(this work)” cells with your measured qₘₐₓ values when available. Engineered materials (functionalized ACFs, GO, MOFs, some modified NaAZ) can show very high qₘₐₓ values for individual ions. However, many such high values are measured under optimized lab conditions (single-ion, ideal pH, no competing cations). Reported ranges for NaAZ are broad—some studies report very high qₘₐₓ for Cu or Pb depending on synthesis and form—so directly comparing numbers requires the same test conditions (pH, ionic strength, solid/liquid ratio). aims to close the gap between high-capacity but slow microporous ion-exchangers and fast, high-surface-area materials (ACF/GO). By adding meso-porosity and small crystal size you should expect faster kinetics and better column performance vs conventional NaAZ and some bio-chars this is a key practical advantage for continuous systems. (Use your t₉₀ and MTZ results to make this point.). Zeolites (NaAZ) and many chitosan-zeolite composites have excellent cyclic stability and straightforward regeneration with NaCl brine. MOFs and some carbon materials may show decreased stability or require harsh regenerates—an important operational consideration. Bio-char and natural zeolites win on cost and scalability. Advanced materials (MOFs, GO, tuned ACFs) can be costly but useful for high-value or small-volume treatments (industrial effluents). Your method’s use of recycled alumino-silicate feed stocks and DES-assisted rapid synthesis strengthens the sustainability and scalability argument.

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Table 8. The Comparison of NaAZ with other adsorbents for heavy-metal removal.

https://doi.org/10.1371/journal.pone.0341007.t008