Abstract
The urgent need to address the severe issue of nitrogen pollution has prompted the search for a functional and easy recycling material. In this study, manganese oxides (MnOx) were loaded on activated carbon (AC), resulting in a composite known as AC-MnOx, for efficient ammonium removal from aqueous solutions. The results indicated a remarkable 15.6-fold increase in ammonium removal efficiency and a fivefold enhancement in removal capacity for AC-MnOx (3.20 mg/g) compared to AC. Under specific conditions (initial NH4+-N concentration of 15 mg/L, adsorbent dose of 2.5 g, pH of 6.5, and temperature of 35 ℃), the highest achieved ammonium removal efficiency reached 94.6%. Furthermore, the study distinguishes the contributions of catalytic oxidation and adsorption in the removal process. The adsorption process was effectively modeled using pseudo-second-order kinetics and Langmuir isotherm models. Interestingly, the amount of oxidation conversion (Ntur) exhibited a linear relationship with the dosage when the initial ammonium concentration was sufficiently high, while the relationship between initial ammonium concentration and the ratio of Ntur to adsorption capacity (Nsur) followed a negative exponential trend. The removal mechanisms involved electrostatic interaction between ammonium and the negatively charged dehydrogenated hydroxyl groups (− OHsur) or cation tunnel in crystal structures of MnOx, ion exchange adsorption, and the oxidation impact of MnOx. This research provides valuable insights into the application of immobilized MnOx media for ammonium removal. Moreover, filling AC-MnOx into constructed wetlands (CW) proved to be an effective method for reducing ammonium pollution, demonstrating its potential in the field of engineering wastewater treatment.
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Introduction
Nitrogen pollution is a pervasive environmental issue confronting the world today, leading to eutrophication, damaging human health, and posing a threat to biodiversity (Cheng et al. 2019; Peng et al. 2018). Ammonium in surface water or groundwater is the primary contributor to nitrogen pollution (Girotto et al. 2020). Thus, finding effective and viable strategies for the rapid removal of ammonium has long been an important subject for researchers, including biological and physicochemical methods (Vocciante et al. 2018).
Although microbial nitrification played an important role in the ammonium removal (Cheng et al. 2019; Liu et al. 2019), microorganism activities were affected by variable environmental conditions significantly, such as temperature, the pH value, and dissolved oxygen (DO) (Ducey et al. 2010; Rajeshwari et al. 2000). The growth and the activity of nitrifying bacteria were inhibited under conditions of low temperature (< 15 °C) (Andersson et al. 2001), low DO concentration (Tatari et al. 2016), and acidic or alkaline (Li et al. 2013). Compared with the biological method, the physicochemical method was considered advantageous for removing ammonium from water conveniently and stably (Chiban et al. 2011a; Cheng et al. 2019; Qiang et al. 2020). It mainly focused on oxidation and adsorption by some kind of composite materials (Chiban et al. 2011b; Li et al. 2015b; Kankanamge et al. 2018). However, they have the drawbacks of a complicated preparation process, low sustainability, and secondary pollution (Cai et al. 2015). Thus, it is an urgent need for an efficient composite material to overcome these disadvantages.
Metal oxide loading was an emerging chemical modification method for adsorption and/or oxidation, which contribute to enhancing the adsorption capacity (Li et al. 2017), broadening the pH adaptability (Tan et al. 2023), and even incorporating catalyst-like properties, such as active manganese oxide (MnOx) loading media (Cheng et al. 2018). Due to the strong oxidization property of Mn(III) (EMn(III)/Mn(II)0 = + 1.50 V) and Mn(IV) (EMn(IV)/Mn(II)0 = + 1.23 V), manganese oxides were widely used to remove toxic compounds (Xie et al. 2018; Joshi et al. 2017; Forrez et al. 2009) and can participate in the biochemical cycle of many elements, such as nitrogen, sulfur, and iron (Lin and Taillefert 2014; Wang et al. 2018; Tebo et al. 2005). As a result of physical and chemical properties, open-framework (layered) structure, a large amount of vacancy sites, and negative surface charges in a wide range of pH, MnOx is regarded as a highly reactive agent for the adsorption and redox transformation of cations (Gadde and Laitinen 1974; Zhao et al. 2018; Wang et al. 2018). Multiple studies have confirmed the catalytic activity of manganese-loaded composite materials in environmental remediation (Lee et al. 2013; Chen et al. 2023). The catalytic activity of MnOx films in biological filters can improve the efficiency of pollutant removal while reducing the consumption of DO (Yang et al. 2019; Huang et al. 2014). Organic matter was preferentially oxidized by MnOx, rather than oxygen (Xie et al. 2018).
Previous work inferred that MnOx could remove ammonium through adsorption and oxidation under low oxygen concentrations in the constructed wetlands (CW) (Li et al. 2021; Wang et al. 2022). However, there was rarely a study on the abiotic effect of MnOx for ammonium removal. Currently, synthetic manganese oxides have been applied as an adsorbent in wastewater treatment (Cheng et al. 2017b; Zhang et al. 2020). Unfortunately, the application of this powdery material was holden back because of reservation difficulty and secondary pollution. Moreover, the chemical catalytic oxidation of ammonium by MnOx was ignored in the research, compromising the credibility of the results. Thus, the immobilized MnOx on the granular medium was considered to be a promising method for wastewater treatment.
As a common adsorption material in wastewater treatment, activated carbon (AC) with substantially lower cost has been widely applied due to its high porosity and large specific surface area (Li et al. 2020; Lyu et al. 2020; Xue et al. 2023). Besides, adjustable surface properties endowed AC with a more powerful performance in removing contaminants after being modified through physical and/or chemical treatment (Zhao et al. 2015; Kolodziej et al. 2014; Xue et al. 2023). It is not clear, whether loading MnOx displays an improved ammonium removal performance of AC for ammonium. Furthermore, the application of composite materials in full-scale filters or CW systems has become a crucial criterion for assessing their effectiveness (Wang et al. 2023). Recently, Fe–Mn co-oxide composites have been successfully applied to enhance nutrient removal in CWs or filters, achieving 90% and 73.81% ammonium removal, respectively (Guo et al. 2017; Zhang et al. 2019). Therefore, it is worth investigating whether MnOx-loaded AC can be organically integrated into biological nitrogen removal scenarios, thereby alleviating the constraints of climate conditions on ammonium removal performance.
In this study, MnOx was loaded on AC to form AC-MnOx. The substance characterization, surface charge, and functional group structure for different adsorbents were measured by X-ray photoelectron spectroscope (XPS), scanning electron microscope (SEM), Brunauer–Emmett–Teller (BET), ZETA potential, and Fourier transform infrared spectroscopy (FT-IR). Prepared AC-MnOx was adopted for investigating ammonium elimination in an aqueous solution through batch experiments. Subsequently, the influence of environmental impact factors on the removal of ammonium would be explored. Furthermore, the contributions of catalytic oxidation and adsorption were distinguished. Several kinds of kinetics and isothermal models were used to identify the adsorption characteristic. The removal mechanism was deeply deduced by discussing the effects of environmental factors on the ratio of catalytic oxidation to adsorption. Finally, the feasibility of using AC-MnOx in CW fillers to enhance the nitrogen removal from wastewater was investigated.
Materials and methods
Preparation of AC-MnOx
Coconut shell AC with a diameter of 2 to 3 mm was purchased in Henan, China. AC-MnOx was prepared through the redox precipitation in consideration of the facile preparation procedure and cost-effective feature. Firstly, 10 g of AC was added into 50 mL of 0.5 mol/L KMnO4 solution under agitation at 400 ± 1 rpm for 1440 min and the purple color of the solution faded so that MnOx was formed on AC quickly at 298 K. The added KMnO4 concentration was selected based on the results of preliminary experiments with different composition, and from an economic perspective (Fig. S1). Then, the solid was separated and washed with distilled water and absolute ethanol until the pH of the filter liquor was close to neutral, which ensured that KMnO4 on the surface of the AC-MnOx was reduced. The obtained solid granulars were dried for 360 min at 378 K and designated as AC-MnOx.
Characterization of AC-MnOx
The morphology of AC-MnOx was analyzed by SEM with energy dispersive X-ray spectroscopy (SEM–EDS, S-4800, Japan Electronics Co., Ltd), the transmission electron microscopy (TEM), and the crystal structure was investigated by XRD (Dmax2550VBPC, Rigaku, Japan). The functional groups of AC-MnOx were identified by an FT-IR spectrophotometer. (Nicolet 6700, Thermal Fisher, USA). The chemical states of MnOx were investigated by XPS (Escalab 250 Xi, Thermal Fisher, USA). The surface potentials of materials were detected by a ZETA analyzer (Brook Haven 90 PALS, USA). The specific surface area of the adsorbent was determined with the BET-specific surface analysis device (Autosorb-iQ, Quantachrome, USA). The concentrations of ammonia, nitrate and nitrite were determined by a UV–vis spectrophotometer (UV-2000, Unico, China) in triplicate according to “Standard Analysis Methods for the Examination of Water and Wastewater.”
Ammonium removal experiment
Effects of external conditions on the ammonium removal
To test the ammonium removal performance of AC-MnOx, 100 mL of 5 mg/L NH4Cl solution was added into a 150-mL conical flask to carry out the static removal experiment. The stability of the ammonium removal efficiency of the two materials was investigated under different treatment conditions (dosage (0.1, 0.5, 1.0, 1.5, 2.0, and 2.5 g), temperature (288, 298, and 308 K), and pH (3.5, 5.0, 6.5, 8.0, and 9.5)). The initial pH was carefully adjusted with 0.1 mol/L HCl or 0.1 mol/L NaOH to avoid repeated adjustments and minimize any potential influence on the solution properties (Nguyen et al. 2021; Nouaa et al. 2023). The static experiment was performed under agitation at 130 ± 1 rpm for 24 h. To ensure the sufficient reaction, the reaction time was extended to 24 h.
Adsorption experiments
To explore the adsorption equilibrium time, the adsorption kinetics and isotherm were studied, based on the equilibrium time. The materials were added into 100 mL of NH4Cl solutions with different concentrations (5, 10, 15, and 25 mg/L). At 288, 298, and 308 K, the experiment was completed at different concentrations. Then, the solution was filtered through a filter with a pore diameter of 0.45 µm for the subsequent detection. Then, the adsorption process was tested under various conditions to explore its kinetics and isotherms. The solid samples were dried at 30 ℃ for further characterization. The ammonium removal involves two mechanisms, catalytic oxidation and adsorption (Lin et al.; Yang et al. 2019; Huang et al. 2014). Thus, the adsorption kinetics and isotherm were fitted with the data obtained by subtracting the quantity of catalytic oxidation nitrogen from the total removal quantity in the adsorption experiment. The total removal quantity of ammonium (Qt, mg/g) at any time t (min, a certain contact time) is calculated as:
The equilibrium removal capacity of each sample is calculated as:
The quantity of nitrate and nitrite generated in catalytic oxidation is regarded as the indicator of ammonium conversion (Ntur, mg/L). The relationship between Ntur and the quantity of ammonium removed by adsorption (Nsur, mg/L) is expressed as:
The quantity of ammonium adsorbed onto the adsorbent (qt, mg/g) at any time t (min, a certain contact time) is calculated as:
The equilibrium adsorption capacity of each sample is expressed as:
where C0 (mg/L), Ct (mg/L), CNO2− (mg/L), CNO3− (mg/L), V (L), and m (g) are, respectively, the initial ammonium concentration, the ammonium concentration at t (min), the nitrate concentration, the nitrite concentration, the solution volume, and the mass of adsorbent; Ce (mg/L) is the equilibrium concentration.
CW application of AC-MnOx
To demonstrate the adaptability of the prepared adsorption and catalytic oxidation materials in practical application scenarios, AC-MnOx was used as a functional substrate and filled into CW for comparison with unmodified AC and inert filler quartz sand (QS). The CW was operated in tidal flow and continuous flow modes, to explore the ability of the functional filler filling region to remove ammonium and the overall nitrogen removal effect of CWs with the participation of microorganisms, respectively.
Statistical analysis
All experiments were carried out in replicates and average values were calculated. Analysis of variance (ANOVA) was performed with Microsoft Excel 2010, whereas the t test was used to assess the significance of results (p-value < 0.05).
Results and discussion
Characterization of AC-MnOx
The crystalline phase analysis by XRD indicated that MnOx was loaded on the surface (Fig. S2). In other words, AC-MnOx has been successfully synthesized. The surface morphology and elements of AC-MnOx were respectively analyzed by SEM and EDS (Fig. 1). The AC with a flat surface with uniformly distributed pores transformed into AC-MnOx with a rough surface composed of a film covered with unevenly distributed aggregates after the in situ redox reaction. According to the result of FT-IR, reactive functional groups on the surface of AC-MnOx were abundant, suggesting the existence of hydroxyl (Benhiti et al. 2020), C = O (1760–1500 cm−1), C–O (1300–950 cm−1), and Mn–O (550–700 cm−1) (Shen et al. 2020) (Fig. S3). The surface of composite AC-MnOx comprised approximately 12.3% (atomic, at. %) manganese and 26.3% (at. %) oxygen, closely resembling the MnO2 elemental ratio (1:2) as observed in the XRD results. Consequently, the loaded proportion of MnOx on AC was estimated to be around 12.3%.
Removal capacity of AC-MnOx
Effects of external conditions on the ammonium removal
The ammonium removal performance of AC-MnOx was higher than AC (Fig. 2a). Under a given concentration, the dosage and temperature were positively correlated with the removal efficiency (Fig. 2a and b), indicating that the ammonium removal reaction was endothermic. However, the removal efficiency tended to be stable if the addition of AC-MnOx was above 2 g. Therefore, 2 g of AC-MnOx was determined as the optimal dosage in subsequent experiments. The ammonium removal efficiency of the tested material was improved by 15.6 times after it was combined with MnOx. The original AC and AC-MnOx exhibited ammonium removal capacities of 0.51 and 3.20 mg/g, respectively. The modified AC showed a fivefold enhancement in ammonium removal capacity. In comparison to other surface-modified adsorbents, AC-MnOx demonstrated significant advantages in terms of its particle form and simple modification process, which allowed for flexible application in various environments and high adsorption capacity for effective treatment efficiency (Table 1). The ammonium removal capacity of AC-MnOx increased with temperature. Figure 2c illustrates the effect of the initial pH on the ammonium removal efficiency of AC-MnOx at 298 K. The removal efficiency (74.1–85.3%) suggested a wide range of pH adaptability for ammonium removal efficiency of AC-MnOx. The negative zeta potential indicated negatively charged surface of AC-MnOx. The enhanced ammonium removal efficiency after MnOx loaded onto AC provided evidence that loading MnOx improved the removal capacity of AC.
Response surface plots and ammonium removal efficiency
The above experimental results and experimental conditions (Table S2) indicated that pH, initial concentration, dosage, and temperature affected the ammonium removal performance of AC-MnOx. The removal efficiency of AC-MnOx was determined through these experiments, and surface response plots were generated for further analysis. The interactions among the dosage (A), pH (B), initial concentration of ammonium (C), and temperature (D) in the ammonium removal by AC-MnOx were analyzed using central component design (CCD). The three-dimensional response surface plots are shown in Fig. S6. The statistical analysis of variance (ANOVA) was performed on the ammonium removal efficiency data of AC-MnOx (Table S3). Low p-values (< 0.001) indicated that the four factors had statistically significant effects on the ammonium removal efficiency of AC-MnOx (Egbosiuba et al. 2020; Schüler et al. 2018). The regression model for the ammonium removal efficiency of AC-MnOx is described by the following equation:
This model determined the relationship between the four factors and the removal efficiency of AC-MnOx. As shown in Eq. (7), the higher the coefficient of the influencing factor, the greater its influence on the removal efficiency. An appropriate dosage posed a positive effect on the ammonium removal efficiency of AC-MnOx. The other three factors had less effect on removal efficiency than dosage, indicating that AC-MnOx was insensitive to these changes under the given experimental conditions. This stability allowed for efficient ammonium removal under different external changes.
Effect of contact time
To explore the impact of contact time on ammonium removal capacity of AC-MnOx, Qe and qe were evaluated under varying ammonium concentrations. Initially, both rates (Qe and qe) showed a rapid increase within the first 60 min, followed by a slower increase over the subsequent 120 min, and eventually reached the equilibrium state after approximately 540 min (Fig. 3a). As the ammonium concentration increased, the maximum qe of AC-MnOx also increased from 0.10 to 0.76 mg/g at 298 K. It is worth noting that the catalytic conversion capacity of ammonium was lower than the adsorption capacity. Across different initial concentrations, the catalytic conversion exhibited only a slight variation, ranging from 2.19 to 3.19 mg/L (Fig. 3b). Conversely, the quantity of ammonium removed through adsorption increased significantly from 2.20 to 14.22 mg/L with the rising initial ammonium concentration.
Adsorption experiments
In this section, all adsorption data were determined by subtracting the quantity of catalytic oxidation from the total removal quantity.
Adsorption isotherms
Isotherms describe the equilibrium states between the adsorbate concentrations in the solid phase and in the liquid phase (Fig. S7 and S8), which can be described by the Freundlich and Langmuir equations (Eqs. (S1-S3)) (Karthikeyan et al. 2008). Isotherm parameters for ammonium adsorption onto AC-MnOx at different temperatures (288 K, 298 K, and 308 K) are provided in Table S4. The regression correlation coefficients (R2) for the Langmuir model (0.992–0.999) were higher than those for the Freundlich model (0.994–0.991) (Figs. S6-S7). The experimental data demonstrated a good fit with the Langmuir isotherm, indicating that the ammonium adsorption process followed a monolayer adsorption mechanism on the adsorbent surface (Sheela et al. 2012).
Thermodynamic studies
A thermodynamic analysis was performed to examine the adsorption of ammonium on AC-MnOx at different temperatures (Eqs. (S4-S7)). The distribution coefficient (K0) of the process increased with temperature, while the Gibbs free energy (ΔG0) was negatively correlated with temperature (Table S5 and Fig. S9). These results suggest that the spontaneity of the adsorption process was proportional to the temperature (Uğurlu and Karaoğlu 2011). Positive values of ΔH0 suggested that the adsorption process was endothermic (Cheng et al. 2017a; Egbosiuba et al. 2020). The high ΔH0 values indicated strong interactions between NH4+ ions and the negatively charged sites on the surface of AC-MnOx (Uğurlu and Karaoğlu 2011). A positive value of ΔS0 indicated increased disorder and randomness in the adsorption process (Kizito et al. 2015). It was worth noting that ΔH0 and ΔS0 were consistently positive, while ΔG0 was negative at high temperatures and positive at low temperatures (Table S5). This suggested that the adsorption of ammonium by AC-MnOx was spontaneous at high temperatures, which aligns with the conclusion presented in the “Effects of external conditions on the ammonium removal” section.
Kinetic models
Three kinetic models (pseudo-first-order, pseudo-second-order, and second-order kinetic model) were applied to analyze the adsorption process (qe), and the fitting curves are displayed in Figs. S10-S12, respectively. The results indicated that the pseudo-second-order model exhibited the highest correlation coefficient among all the models (Table S6), suggesting that the adsorption process was primarily governed by a chemical reaction (Cai et al. 2020). As the concentration of ammonium in the solution increased, it may stimulate the adsorption onto the deep binding sites of AC-MnOx. This finding confirmed that the adsorption process was influenced by both the ammonium content in the solution and the availability of active multilayer adsorption sites on AC-MnOx (Shafiof and Ejhieh 2020).
Ammonium removal mechanism by AC-MnOx
Changes in AC-MnOx before and after the reaction
To study the phase changes of Mn species during the oxidation process of ammonium, XPS analysis was carried out on fresh and used AC-MnOx (Fig. S4). Based on the XPS spectra of the fresh AC-MnOx (Fig. 4a) and the previously reported peak areas corresponding to different valence states of Mn (Kumar et al. 2016; Li et al. 2015a; Sharma and Zhai 2009), Mn(III) was the dominant valence state in the fresh AC-MnOx (Liu et al. 2021). Compared with the fresh AC-MnOx with the used AC-MnOx, it was observed that the content of Mn(III) decreased while the contents of Mn(II) and Mn(IV) increased in the latter (Fig. 4b). The oxidation state of manganese can be determined by analyzing the satellite separation of Mn3s splitting (△Es). Different valence states of Mn exhibit different △Es values. The △Es (Mn3s) ranges for Mn(IV) and Mn(III) were reported as 4.7–4.8 and 5.3–5.4, respectively (Subramanian et al. 2006; Kim and Shim 2010). The △Es for the fresh AC-MnOx was measured as 5.0 eV (Fig. S5), which falls between the typical △Es values of Mn(IV) and Mn(III), indicating the coexistence of Mn(IV) and Mn(III) in the fresh AC-MnOx. The △Es for the used AC-MnOx was determined as 4.8 eV, which was consistent with the typical △Es value of Mn(IV). Based on the relevant data (Table S1), the average oxidation states of Mn in the fresh and used AC-MnOx were estimated as 3.1 and 3.0, respectively.
In addition, O1s spectra could be used to estimate the oxidation state of manganese. In Fig. 4c and d, the O1s spectra exhibit asymmetry and can be deconvoluted into three peaks at 529.9 eV, 531.0 eV, and 531.8 eV. These peaks were assigned to Mn–O–Mn bonds of tetravalent oxide, Mn–O–H bonds of hydrated trivalent oxide, and H–O–H bonds of residual water, respectively (Sharma and Zhai 2009). The average oxidation state (OS) of Mn can be determined from the intensity of Mn–O–Mn and Mn–O–H peaks (i.e., SMn–O–Mn and SMn–O–H) (Toupin et al. 2004):
The oxidation state of manganese in the fresh AC-MnOx (OS = 3.77) was higher than that in the used AC-MnOx (OS = 3.33). This change in the average valence state of manganese indicated that MnOx was involved in the oxidation of ammonium.
Catalytic oxidation of ammonium
As previously mentioned, nitrate and nitrite were detected in the solution after the removal of ammonium using AC-MnOx, while manganese ions were not detected. This implied that AC-MnOx acted as a catalyst in the oxidation process. The ammonium removal process by AC-MnOx involved adsorption and catalytic conversion. Thus, the relationship between the ratios of surface adsorption (NsurRE) and catalytic conversion (NturRE) to total ammonium removal can be expressed as follows:
To further explore the catalytic conversion rate of AC-MnOx on ammonium, the relationship between NturRE and NsurRE was examined under different initial ammonium concentrations (Fig. 5a). As the initial concentration of ammonium increased, the efficiency of ammonium removal decreased. The majority of the total removed ammonium was attributed to adsorption (Nsur), while the fraction of ammonium removed through catalytical conversion NturRE% was significantly lower and reduced with the increasing initial ammonium concentration. This suggested that the catalytic oxidation process occurred at a slower rate compared to adsorption. Initially, a large amount of ammonium was rapidly adsorbed, followed by a decrease in the adsorption rate as adsorption continued.
Figure 5b demonstrates that the catalytic oxidization performance of AC-MnOx improved gradually with increasing initial ammonium concentration. The value of Ntur was positively correlated with the dosage of AC-MnOx. When the initial ammonium concentration was 25 mg/L, a linear equation with an R2 of 0.997 was obtained to fit the catalytic conversion of nitrogen with the AC-MnOx dosage. Under conditions of sufficient ammonium, AC-MnOx with an equivalent dosage resulted in a similar quantity of catalytic nitrogen oxides (Ntur). This indicated that the catalytic oxidation reaction was completed first, accompanied by continuous electrostatic adsorption. However, under the same dosage conditions, the quantity of ammonium adsorbed on the surface (Nsur) increased with higher ammonium concentrations. This led to a reduction in the proportion of catalytic oxidation (NturRE %).
Effects of pH and temperature on Ntur/Nsur
The pH of the solution had an impact on both the adsorption capacity (Nsur) and catalytic conversion (Ntur) of AC-MnOx with respect to ammonium (Table 2). Under an initial concentration of 5 mg/L, the Ntur/Nsur ratio increased as the pH increased (Fig. 6a). In an alkaline environment, ammonium could react with OH– to form NH3·H2O. This reaction reduced the number of ammonium cations available to enter the tunnels within the MnOx crystals to stabilize the structure (Wang and Li 2003). As a result, when the pH increased, the proportion of ammonium underwent increase in the catalytic conversion (Ntur). Furthermore, the H+ could occupy the binding sites of ammonium and react with MnOx, resulting in a decrease in NturRE%. Therefore, in the presence of sufficient OH– ions, a higher NturRE% could be achieved due to the avoidance of metal ion dissolution caused by high alkalinity.
The initial ammonium concentration showed a negative exponential relationship with Ntur/Nsur (R2 = 0.993–0.998) (Fig. 6b). Furthermore, with an increase in C0, Ntur/Nsur showed a greater increase at higher temperatures. This suggests that the impact of the initial concentration on catalytic conversion was more significant than on the adsorption process under higher temperatures. Under the same initial concentration, elevated temperatures enhanced the performance of catalytic oxidation, which resulted in an increased Ntur/Nsur ratio.
Potential adsorption mechanisms
The adsorption mechanism of AC-MnOx was based on the interactions between the adsorbent and adsorbate NH4+, such as physical adsorption, electrostatic attraction, and ion exchange (Hu et al. 2020). AC-MnOx has a lower surface area but higher NH4+-N adsorption capacity, which was contradicted with the expected behavior of physical adsorption. This suggested that physical adsorption was not a major contributor in NH4+-N adsorption. Instead, chemical adsorption appeared to be the dominant process, consistent with the observed kinetic results. Although the cation exchange capacity (CEC) of AC-MnOx was not determined in this work, a previous study found limited NH4+-N adsorption capacity through ligand exchange (Nguyen et al. 2021). The loading of MnOx on AC-MnOx led to the presence of more surface functional groups, such as hydroxyl, carboxyl, and carbonyl, which contributed to the enhanced NH4+ adsorption capacity. Additionally, the high O/C ratio (0.45) of AC-MnOx resulted in a strongly polar surface (Takaya et al. 2016), promoting electrostatic interactions between NH4+ and AC-MnOx. In general, chemical bonding and electrostatic attraction play predominant roles in the NH4+ adsorption process.
Removal mechanisms by catalytic oxidation
Based on the decreasing trend of DO in the solution after the reaction, the catalytic oxidation mechanism can be speculated as follows:
The above two reactions (Eqs. (9) and (10)) can be combined as follows:
The removal mechanism of ammonium by AC-MnOx could be inferred (Fig. 7). Mn(III) originally present in AC-MnOx was oxidized to Mn(IV) by DO, resulting in the generation of OH− (Eq. (9)). Subsequently, Mn(IV) was reduced by H2O, leading to the regeneration of –OHsur and the release of H+ ions (Eq. (10)) (Wang et al. 2014; Meng et al. 2020). This reduction/oxidation process involving Mn species occurred. The combination of these reactions can be expressed in Eq. (11). Furthermore, OH− ions, escaping from the surface groups (–OHsur), such as C–OH, –COOH and Mn–OH, caused the surface of AC-MnOx to become negatively charged (Guo et al. 2017; Zhao et al. 2018). As a result, AC-MnOx attracted NH4+ into its surface. In addition, NH4+ ions entered the cation tunnel of MnOx through electrostatic adsorption and occupied oxygen vacancies (Wang and Li 2003). With the high oxidation activity of Mn(III), the reaction between Mn(III) and NH4+ ions led to form Mn(II) and nitrate (Eq. (12)). The electrostatic repulsion between AC-MnOx and the negative charged ions (such as chloride ions, nitrate, and nitrite) decreased, thereby reducing their influence on the adsorption process and promoting the release of them into the solution. After finishing the catalytic oxidation, AC-MnOx continued to adsorb ammonium.
CW application of AC-MnOx on ammonium removal
The CW construction and operating parameters are shown in the Fig. S13 and Table S8, respectively. Figure 8 shows the impact of AC-MnOx on ammonium removal performance in CWs. After 1 day of feeding CWs with NH4+-N synthesis wastewater, the average NH4+-N removal efficiency in the AC-MnOx filling regions reached 69.37%, while it was 23.87% in the AC region, and only 7.08% in the inert CW-control (Fig. 8a). The average NH4+-N removal rates for these three groups were 28.04, 13.08, and 3.88 mg/(m3⋅h), respectively. As the HRT increased from 1 to 3 days, the NH4+-N removal efficiency improved, but the removal rate decreased due to the slower adsorption rate of the adsorbent. The highest removal rate achieved in the AC-MnOx filling regions was 92.6%. To investigate the response of AC-MnOx fillers to high nitrogen loads, the influent NH4+-N concentration was increased to 15 mg/L after 5 cycles of operation (Fig. 8b). The results showed that the average NH4+-N removal rate significantly increased for all three CWs, with the highest 64.97 mg/(m3⋅h) in CW-AC-MnOx at an HRT of 1 day. This illustrated that AC-MnOx provided a favorable environment for microorganisms. Whereafter, the CWs were operated in continuous flow mode, and the removal rate of CW-AC-MnOx reached a high 112.89 mg/(m3⋅h) (Fig. 8c). Overall, the use of AC-MnOx significantly improved the nitrogen removal performance of CW and demonstrated its ability to synergistically remove nitrogen with the action of microorganisms.
Conclusion
In this study, MnOx was loaded on the surface of AC for ammonium removal. Ammonium removal experiments showed that the ammonium removal performance of the synthesized material was improved after loading on the MnOx film (15.6 times than before). The dosage is the main factor affecting the removal of ammonium. The ammonium removal process by AC-MnOx involved adsorption and catalytic conversion, and the latter reacted more slowly than the former. Besides, the increase in initial concentration improved the proportion of adsorption. The ammonium removal mechanism by AC-MnOx included ion exchange, electrostatic adsorption, and catalytic oxidation. Overall, this work proposed a novel strategy for engineering practices in nutrient removal and provided theoretical support for a profound understanding of the remediation process. Future research efforts should focus on the long-term performance of AC-MnOx in continuous removal of ammonium wastewater.
Data availability
The authors declare that the main data supporting the findings of this study are contained within the paper and its associated supplementary information. All other relevant data are available from the corresponding author upon reasonable request.
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This work was supported by the National Natural Science Foundation of China (Grant No. 52170152), the Science and Technology Innovation Action Plan Social Development Key Science and Technology Project of Shanghai (No. 21DZ1202402), the National key research and development project (No. 2021YFC3000102), the Youth Program of National Natural Science Foundation of China (Grant No. 51909034), and the Fundamental Research Funds for the Central Universities and Graduate Student Innovation Fund of Donghua University (No. CUSF-DH-D-2022066).
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Yifei Wang: writing—original draft and writing—review and editing; Xinyi Jiang: experimental design, and writing—original draft; Xinshan Song: writing—review and editing, supervision, and funding acquisition; Xin Cao: funding acquisition, data curation, and formal analysis; Zhongshuo Xu, Yuhui Wang, Jianfeng Li, Nan Wu, and Junhong Bai: conceptualization, validation, methodology, investigation, project administration, and supervision.
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Wang, Y., Jiang, X., Song, X. et al. Manganese oxide–loaded activated carbon for ammonium removal from wastewater: the roles of adsorption and oxidation. Environ Sci Pollut Res 30, 110161–110174 (2023). https://doi.org/10.1007/s11356-023-30086-7
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DOI: https://doi.org/10.1007/s11356-023-30086-7