Introduction

Water environment deterioration and eutrophication of natural water bodies such as rivers, lakes and wetlands in China have been caused wide public concern in the last few decades1. High concentration NH4+-N is commonly present in textile, fertilizer, petrochemical, pharmaceutical industrial wastewater2,3,4,5. Meanwhile, nitrogen (N) is one of the indispensable nutrients for crops6,7. Therefore, it is necessary to recover NH4+-N from wastewater containing NH4+-N. Several methods have been applied to pretreat wastewater containing high concentration NH4+-N, such as steam-stripping / air-stripping means8, biological denitrification technology9,10 and MAP method. Struvite precipitation method11,12,13,14 is considered to be an attractive treatment option due to its simple operating, high efficiency, low cost, and can recover NH4+-N as slow-release fertilizer15,16,17, but different reaction conditions directly affect the recovery efficiency of struvite.

Many researchers have been working to improve the reaction conditions of struvite precipitation, include the solution of pH18, the molar ratio of Mg, P, N3 and combined struvite precipitation and microwave irradiation19. To the best of my knowledge, the sequence of adding reagents is an important aspect of the mineral flotation influencing factors studied by Zhang Qidong20 and Wang Jizhen21. But there have been few reports on the effect of the order of reagent addition on NH4+-N recovery and removal. In addition, in practical applications, the reagent addition sequence introduced in this article is mainly applicable to actual wastewater with little or no Mg salt and P salt, such as coking wastewater19 and hydrometallurgy wastewater22.

Based on the aforementioned information, the effect of the reagent addition sequence of solution on the formation of struvite was investigated. The corresponding precipitation products were characterized by scanning electron microscopy (SEM) and X-ray diffraction (XRD).

Results and discussion

The effect of reagent addition sequence on NH4+-N recovery efficiency

The NH4+-N concentration of solution, pH, and the molar ratio of Mg, P, and N were 500 mg L−1, 9.5, and 1.3:1:1, respectively. The reaction mechanism of struvite formation can be expressed as the following formula:

$${{\rm{N}}{\rm{H}}}_{4}^{+}+{{\rm{M}}{\rm{g}}}^{2+}+{{\rm{H}}{\rm{P}}{\rm{O}}}_{4}^{2-}+6{{\rm{H}}}_{2}{\rm{O}}\to {{\rm{M}}{\rm{g}}{\rm{N}}{\rm{H}}}_{4}{{\rm{P}}{\rm{O}}}_{4}\cdot 6{{\rm{H}}}_{2}{\rm{O}}\downarrow +{{\rm{H}}}^{+}$$
(1)

It can be seen from Fig. 1 that the sequence of reagent addition has a great influence on the NH4+-N recovery efficiency. Among the four modes, the M-IV has the highest NH4+-N recovery efficiency, up to 90.80%. The NH4+-N recovery efficiency in the other three modes is 66.17%, 60.70%, and 84.08%, respectively.

Figure 1
figure 1

NH4+-N recovery efficiency (%) under four modes.

The significant difference in the recovery efficiency of NH4+-N may be related to the sequence of pH adjustment of the solution. As elucidated by Eq. (1), when the Mg salt and the P salt reacted with the NH4+-N wastewater to form struvite crystallization, the pH of solution will decrease. It is reflected in the Fig. 1 that when the pH was adjusted after reagent reaction (M-III and M-IV), the NH4+-N recovery rate were larger than that of pH value adjusted before the reaction (M-I and M-II). When the NaOH solution was used to adjust the pH to 9.5, it was confirmed that the latter two (M-III, 2.4 ml and M-IV, 2.4 ml) used more alkaline solution than the first two (M-I, 1.3 ml and M-II, 1.2 ml). This is a powerful explanation of why the latter two (M-III and M-IV) are significantly better than the former two (M-I and M-II) for NH4+-N recovery rate. Consequently, one of the mechanisms by which different reagent addition sequences lead to different ammonia nitrogen recovery rates can be attributed to the discrepancy in the final NaOH addition amount. Additionally, other possible causes will be explained in the next section on the effect of reagent addition sequence on precipitates mass recovery.

The effect of reagent addition sequence on mass of precipitates

From Fig. 2 can be seen that the sequence of reagent addition has also great influence on the yield of precipitates. Among the four modes, the M-IV has the highest mass of sediment, up to 896 mg. The amount of sediment in the other three modes is 689 mg (M-I), 649 mg (M-II), and 886 mg (M-III), respectively. Compared with Fig. 1, it can also be observed that the higher NH4+-N recovery efficiency, the more precipitates are produced.

Figure 2
figure 2

Mass of precipitates (mg) under four modes.

Meanwhile, the reason why the M-IV is better than the M-III is probably that the difference in seed amount of crystals formation, which is conducive to the increase of precipitation23. For M-IV, it was ensured that Mg salt and P salt solids were dissolved in NH4+-N wastewater, respectively, before adjusting the pH to 9.5, then the three reagents reacted with each other and formed the initial crystal seed24. By contrast, P salts took longer (30 seconds–1 minute) to dissolve completely than Mg salts when Mg salt and P salt reagents added into NH4+-N wastewater, which affected the formation of crystal seed, leading to a bit lower mass of precipitates in M-III than that of M-IV25.

SEM analyses

Figure 3 shows the SEM images of products obtained under different reagent addition sequences. According to the results shown in Fig. 3, the morphology of products formed in four modes was quite different. In particular, the orthorhombic crystal phases of M-II and M-IV differ greatly, in which M-II is broad and dense and M-IV thin and loose. This is because in order to promote the formation of precipitation, the compaction degree of solids is affected, thus becoming loose and difficult to further precipitate. This result is similar to Song et al.26. This also in accord with the results analyzed in Fig. 1. The amount of sodium hydroxide has an effect on the morphology.

Figure 3
figure 3

SEM images of products under different reagent addition sequences.

X-ray diffraction

Figure 4 shows the XRD spectra of products obtained under different reagent addition sequences. As can be seen from the XRD diffractogram (Fig. 4), the (020), (111) and (040) reflections of the four spectra are almost identical with the standard struvite spectrum, which can be confirmed that struvite crystal is the mainly component in the obtained precipitates according to JCPDS files (15–0762). For the peak’s intensity of (022) and (211) reflection, M-III and M-IV were stronger than that of M-I and M-II. This is due to the more sodium hydroxide retained by M-III and M-IV, which is consistent with the results obtained in Fig. 1.

Figure 4
figure 4

The XRD spectra of products under different reagent addition sequences.

Conclusions

The experimental results showed that the sequence of reagent addition has a great influence on NH4+-N recovery and mass of precipitates. The optimal NH4+-N recovery efficiency (90.80%) appeared in M-IV, that is, using 50% NH4+-N wastewater to dissolve completely the Mg salt and the P salt, respectively and then simultaneously poured into a beaker to mix the solution evenly and adjust the pH to 9.5. The mechanism for M-IV mainly resulted from the more alkali than M-I and M-II, and the more amount of initially crystal seed formation than M-III.

Materials and Methods

Materials

All reagents were of analytical grade and purchased in Shantou Xiqiao Science Co., Ltd., Guangdong, China. P salt and Mg salt used in the experiment were disodium hydrogen phosphate dodecahydrate (Na2HPO4·12H2O) and magnesium chloride hexahydrate (MgCl2·6H2O), respectively. Ammonium chloride (NH4Cl) was used to prepare simulated NH4+-N wastewater. The initial pH of solution was adjusted with 1 mol L−1 NaOH and HCl. All solvents were deionized water.

Procedures of experiments

Under room temperature (25 ± 2°C), four modes of reagent addition sequences are as follows: Three 200 ml beakers were filled with 100 ml 500 mg L−1 synthetic NH4+-N wastewater. In the beaker I (M-I), the initial pH of solution was adjusted to 9.5 firstly, then added solid Mg salt and P salt at the same time and stirred to dissolve completely. In the beaker II (M-II), solid P salt was added and stirred to dissolve completely, then adjusted the pH of the mixture to 9.5, following Mg salt was added and stirred to dissolve completely. For the beaker III (M-III), Mg salt and P salt were added at the same time and then stirred to dissolve completely, following adjusted the pH of the solution to 9.5. As for the beaker IV (M-IV), Mg salt and P salt were first added into a 100 ml beaker containing 50 mL of NH4+-N wastewater and then stirred to dissolve completely, respectively. Next simultaneously poured into a 200 ml beaker to mix the solution evenly and adjust the pH to 9.5. Four modes of reagent addition sequences and schematic diagram of struvite formation have shown as Fig. 5.

Figure 5
figure 5

Four modes of reagent addition sequences schematic diagram of struvite formation.

The mixed solution of the four beakers was stirred by a magnetic stirrer to promote the formation of precipitates and then standing for 30 min to make the precipitation complete. After that, precipitation yield was obtained after filtrating through a 0.45-μm filter membrane, washing by deionized water three times and drying in an oven at 50°C. The content of NH4+-N in the filtrate was determined. All batch experiments were performed in triplicate and the average was taken as the experimental results.

Analytical methods

The morphology of the precipitates was characterized using a scanning electron microscope (SEM, MLA650F, FEI, Hillsboro, USA). The crystal patterns of the synthesized struvite was obtained by X-ray diffractometer with Cu-Kα radiation (40KV, 40 mA), from radiation angle 10–60°(XRD, DX-2700, Shjingmi, Shanghai, China). The content of NH4+-N in solution was measured by visible spectrophotometer (722 N, INESA, Shanghai, China) with a wavelength of 420 nm according to Nessler’s reagent spectrophotometry method.

The calculation Eq. (2) for the recovery of NH4+-N is:

$$Y=\frac{{C}_{O}-{C}_{t}}{{C}_{O}}\times 100$$
(2)

where Y (%) is the recovery efficiency of NH4+-N, C0 refers to the initial NH4+-N concentration (mg L−1) and Ct refers to the equilibrium NH4+-N concentration (mg L−1) of the solution.