Introduction

Environmental pollution by pharmaceutical compounds is considered as one of the most serious issues in recent years1,2. For the treatment of pharmaceutical wastewater and for removing pollutants before those are released into the environment, identification of the most efficient method is a challenge3. Pharmaceutical wastewater can be treated using physical4, chemical, biological5, as well as combined methods6. The Advanced oxidation processes7 including advanced oxidation based on the sulfate radicals8, ultraviolet–visible9, natural sunlight10, Fenton oxidation11, electrochemical12, nanocomposite catalysts13, and sonolysis and sono-Fenton14 have been widely used to remove pollutants from pharmaceutical wastewater with great performance. The formation of radicals during these processes leads to the oxidation of organic pollutants in aqueous solutions. In comparison to other methods, photocatalysis offers several advantages, such as high efficiency, low cost, design of suitable catalysts for specific wastewaters, and high corrosion and temperature stability15,16,17. Titanium dioxide (TiO2) has been widely used as a catalyst in the degradation of organic compounds and pharmaceutical pollutants since it is a light-sensitive semiconductor (including UV and visible light)18,19. The formation of valence band holes and conduction band electrons during photocatalysis produces oxidation–reduction media in wastewater. It can easily degrade organic compounds and convert them into non-toxic compounds such as CO2 and water20,21. Titanium dioxide is a polymorphic material with three crystalline phases: anatase, rutile, and brookite. The anatase phase is more photocatalytically active than the rutile phase22,23. In order to enhance the TiO2 photocatalyst activity, it is important to use smaller particles (nano size), as smaller particles have higher specific surface areas24. The removal of titanium dioxide nanoparticles after treatment reduces the benefit of this photocatalyst, and immobilization of titanium dioxide (TiO2) onto supporting materials can be performed, but immobilization reduces the specific surface area in comparison with a homogenous catalysts25. On the other hand, fast recombination of generated electron–hole pairs can decrease the activity of titanium dioxide photocatalyst26. Therefore, some other semiconductors such as ZrO2 are used to improve of the activity of TiO2. ZrO2 doping can slow down the electron–hole pair recombination, strengthen the material and increase surface area and anatase to rutile crystal phases ratio27,28. ZrO2-TiO2 photocatalyst has been used to degrade organic compounds, which in this compound, ZrO2 acts as support or photocatalyst in the system29.

The addition of a small amount of ZrO2 to TiO2 can increase the surface area because ZrO2 inhibits anatase to rutile phase transitions, densification, and crystallite growth by providing dissimilar boundaries30. It was observed that changes in surface chemistry, particularly acidity improve the photocatalyst activity31. In this binary catalyst, holes trap such as the hydroxyl groups, prevent electron–hole recombination and oxidation–reduction reactions, and increase quantum yield31. In addition to ZrO2 nanoparticles, it is necessary to be added another compound to these binary metal oxides to improve the surface area of the TiO2 photocatalyst as well as recovery of TiO2 from treated wastewater32,33. Magnetic nanoparticles, such as Fe3O4, are suitable for this purpose. A Fe3O4@TiO2 photocatalyst has been synthesized to degrade Bisphenol A under visible and long-wavelength UV light irradiation. Moderate iron loading reduced hole-pair separation effectively, and shifted the bandgap in the visible range. Further, the magnetic properties of Fe3O4 play a critical role in recovering the used catalyst from the solution, which facilitates practical applications of the Fe3O4@TiO2 photocatalyst34. Fe3O4@SiO2@g-C3N4/TiO2 nanocomposite was used to remove dye pollutants. It has been found that the 10 wt.% g-C3N4/TiO2 composite catalyst can degrade over 91% of anionic and cationic dyes35. Therefore, it is possible to combine the three compounds to degrade toxic and harmful pollutants in wastewater. In recent years, non-steroidal anti-inflammatory drugs (NSAIDs) have been increasingly used for the treatment of COVID-1936,37. Therefore, it is predicted that pharmaceutical-produced wastewater containing NSAIDs such as naproxen will increase and it will be very important to develop an effective method of degradation these compounds from the wastewater. The degradation of naproxen by H2O2-modified titanate nanomaterial and Bi-modified titanate nanobulks under visible light irradiation has been successfully accomplished38,39. In previous works, each of these metal oxides was used separately as a catalyst to remove various contaminants40,41,42,43, but the interaction of the three metal oxides of Fe3O4, TiO2 and ZrO2 together and its function to remove pharmaceutical contaminants can produce a synergistic effect. The difference in physical and chemical properties of each component of these nanophotocatalyst makes it unique. A nanocomposite with magnetic, stable, and high photocatalytic properties was finally synthesized44,45. TiO2 has a band gap of 3.2 eV for anatase, and 3.0 eV for rutile46,47. The ZrO2 is used as a photocatalyst in heterogeneous reactions due to its semiconductor properties (type n). The band gap energy of ZrO2 varies from 3.25 to 5.1 eV depending on the sample preparation48,49,50,51,52,53,54,55. Its common band gap energy is 5 eV55. It has a wide bandgap and a highly negative flat-band potential, which can be used for hydrogen production through water decomposition55,56. Magnetic properties of Fe3O4 nanoparticles make recyclable nanocomposites possible. Furthermore, the excitation range of nanocomposites synthesized from Fe3O4 can be used in the visible light range due to their unique optical properties.

The Response surface methodology (RSM) is a widely used mathematical and statistical method for modeling and analyzing a process in which a response is affected by multiple variables, and its goal is to optimize the response57,58. Synthesis of Fe3O4/TiO2/ZrO2 nanocomposite can improve the photocatalytic property of catalyst. The synthesis of these nanoparticles individually can have some disadvantages such as a wide energy gap, activity only in UV, lower photocatalytic activity, However, their composite synthesis will offer advantages such as higher magnetic properties, recyclable, higher stability and activity, and enhanced photocatalytic activity59,60,61,62,63,64,65,66,67. The Box–Behnken design (BBD) was used in this study due to its rotatable or nearly rotatable second-order design. The percentage of naproxen degradation was selected as the experimental design response68,69.

The current work is focused on the synthesis of a new ZrO2/TiO2/Fe3O4 nano-photocatalyst with high photocatalytic activity and reusability for the pharmaceutical wastewater treatment. Its performance has been evaluated in the removal of naproxen from pharmaceutical wastewater under UV light. The synthesised photocatalyst has been characterized with methods such as X-ray diffraction (XRD), Energy Dispersive X-Ray (EDX), Scanning Electron Microscope (SEM), Brunauer–Emmett–Teller (BET), Fourier Transform Infrared Spectroscopy (FTIR), X-ray Photoelectron Spectroscopy (XPS), Electron energy-loss spectroscopy (EELS), and Photoluminescence (PL). We investigated various factors including the initial concentration of naproxen, initial pH of the solution, photocatalyst dosage, and time until the optimal degradation efficiency was obtained using the RSM method.

Experimental and methods

Materials

Titanium (IV) iso-propoxide 97%, zirconyl(IV) chloride octahydrate (ZrOCl2.8H2O, 98%), and Iron (II) chloride tetrahydrate (≥ 99%) and iron (III) chloride hexahydrate(≥ 99%) were used as a precursors for the synthesis of TiO2, ZrO2, and Fe3O4 respectively. Ethanol was obtained from Sigma-Aldrich and utilized without any further processing. Deionized water (DI-water) was also used in the experiment. Sulphuric acid (H2SO4, 0.1 M) and sodium hydroxide (NaOH, 0.1 M) were used for the adjustment of the pH of the solution. (S)-6 methoxy α-methyl 2-naphthaleneaceticb sodium salt was purchased from Sigma Aldrich and its aqueous solution used for degradation experiments. In Table 1, naproxen's physical and chemical properties are shown.

Table 1 Physical and chemical properties of naproxen.

Synthesis of nanoparticles

ZrO2 nanoparticles

The co-precipitation method was used for the synthesis of ZrO2 nanoparticles. Firstly, ZrOCI2.8H2O was dissolved in deionized water. Then, 2 M NaOH solution was added to the solution in order to achieve a solution with a pH of 10. The solution was gently stirred for 1 h. After that, the precipitate was filtered, washed with distilled water to reach neutral pH. The obtained powder was dried in an oven at 60 °C for 24 h and then calcined at 700 °C for 10 h70.

TiO2 nanoparticles

Sol–Gel method was used for the preparation of TiO2 nanoparticles. 15 mL Titanium (IV) isopropoxide was added into 60 mL ethanol. A magnetic stirrer was used to mix the solution for 30 min. 10 mL deionized water in a drop-wise fashion was added into the mixture until hydrolysis reaction occurred in the system. The obtained white gel was dried at 100 °C and later calcined at 450 °C for 2 h71.

Fe3O4 nanoparticles

Known amounts of FeCl3.6H2O (0.605 g) and FeCl2.4H2O (0.215 g) were dissolved in deionized water. Then, the obtained solution was placed in an ultrasonic homogenizer for 5 min. After that, 60 mL of 1 M NaOH was added dropwise into solution under ultrasonic at 70 °C. After 60 min, the brownish powder was obtained at a pH of 13.4 and it was separated from the solution using a centrifuge. Finally, it was calcined at 300 °C for 1 h72.

ZrO2/TiO2/Fe3O4 nano-photocatalyst

ZrO2/TiO2/Fe3O4 photocatalysts were prepared using solid-state dispersion method. ZrO2, TiO2, and Fe3O4 nanoparticles were mixed at a ratio of 4:8:1 in ethanol solution. The resultant ternary oxide was stirred at a constant rate of 300 rpm for 15 min. Then, ethanol was removed from a mixture of nanocomposite by evaporation. Then, the product was dried at 110 °C and calcined at 450 °C for 6 h to obtain ZrO2/TiO2/Fe3O4 nanocomposite photocatalyst60. The mixing ratio of used components in the synthesized nanocomposite was selected based on the highest efficiency of naproxen degradation under the same operation conditions. The best ratio was achieved (4:8:1) of the ZrO2, TiO2, Fe3O4 compounds.

Photocatalyst characterization

The mineralogical analysis of the prepared nanoparticles was characterized by X-ray diffraction (Inel France, Equinox 3000) with Cu radiation. SEM(AIS2100). It was used to determine the surface morphology and microstructure of ZrO2/TiO2/Fe3O4 nanocomposite photocatalyst. The Fourier-transform infrared spectroscopy (VERTEX 70, Bruker, USA) in the wavelength range from 400 to 4000 cm−1 was used to analyze the chemical bonding in a photocatalyst. Texture properties of nanoparticles was investigated using TriStar-II-Series, Micromeritics Instrument Corporation, USA. The specific surface area of photocatalysts was determined via the N2 adsorption–desorption and Brunauer–Emmett–Teller (BET) model. Barrett-Joyner–Halenda (BJH) method was used to calculate the size of pores and pore size distribution using adsorption–desorption curves. Powder samples for XPS analysis are prepared in the form of pellets in the laboratory (the powder should be large enough to cover a surface of 1.5 × 1.5 cm), then the samples should be placed in a vacuum chamber after preparation. A PHI Perkin-Elmer Model 5400 instrument was used to record XPS spectra. The EELS analysis was obtained using a sub-nanometer probe size using the GIF2000 Filter. The PL Spectroscopy was recorded by Avaspec-2048-TEC model spectrometer.

Point of zero charge determination

An amphoteric oxide method was used to determine the point of zero charge of the photocatalyst73. In order to determine the point of zero charge (PZC), 0.25 g of the synthesized photocatalyst was added into the solution with the same ionic strength and different pH values. The synthesized nanocatalyst was added to 50 mL of 0.1 M NaNO3 solution. The pH of solution was adjusted in the range of 3–9 using 0.1 M H2SO4 and 0.1 M NaOH. The pH of solution was measured before and after 24 h mixing and those were called pHi and pHf respectively. The plot of pH changes (ΔpH) as a function of initial pHi was used for the determination of PZC73.

Optimization of the photocatalyst Activity

In order to optimize photocatalyst activity, the RSM has been used. Design Expert 8.0 software (Stat-Ease, Inc., USA) was used to design experiments and analyze mathematical modeling. Each experiment was performed in duplicate. Box–Behnken design (BBD) was applied in this study because of its rotatable or nearly rotatable second-order design. The “y” was the response (the percentage of naproxen degradation). We evaluated four independent variables, including catalyst loading dosage, initial concentration of naproxen, time and pH value in order to find an optimal condition:

$$y=f({x}_{1},{x}_{2},{x}_{3},{x}_{4})$$
(1)

Photocatalyst activity

ZrO2/TiO2/Fe3O4 Photocatalyst was used for the degradation of naproxen in a pharmaceutical synthetic solution. The experiments were conducted based on the conditions in Table 2. In this study, the effects of solution pH, time, initial naproxen concentration, and photocatalyst loading dose on naproxen degradation were evaluated. To determine the adsorption behaviour of the photocatalyst, the solution kept was in the dark for half an hour. The reactor was irradiated immediately after adding the photocatalyst. For each experiment, a 150 W UV light source has been used for irradiation (The intensity was kept as 15 W/m2). At the end of each experiment, centrifugation with 12,000 rpm for 20 min have been performed for each withdrawn sample followed by absorbance measurement using UV‐Vis (Shimadzu UV2401PC) at λ = 230 nm. The efficiency of designed photocatalysts for the degradation of naproxen was calculated as follows:

Table 2 Operating parameters for degradation of naproxen experiment.
$$NPXR\left(\%\right)=\left(\frac{{C}_{i}-{C}_{f}}{{C}_{i}}\right)\times 100$$
(2)

where Ci and Cf are the naproxen concentration before and after degradation reaction respectively.

Reusable photocatalytic properties

Reusability tests were conducted for ZrO2/TiO2/Fe3O4 Photocatalyst. Briefly, the selected photocatalyst being used in the degradation test of naproxen was separated from solution using a 1.3 Tesla magnet. Used photocatalysts were rinsed in distilled water and irradiated under UV light for 12 h. In order to evaluate the reusability of a photocatalyst, seven successive experimental runs were conducted.

Results and discussion

Characterization

XRD analysis

The constituting phase, crystalline size, and crystalline structures of the ZrO2, TiO2, and Fe3O4, nanoparticles, and ZrO2/TiO2/Fe3O4 nanocomposite characterized using XRD, which are depicted in Fig. 1. For ZrO2, the primary characteristic diffraction peaks appeared at 2θ = 30°, 35°, 50.8°, 60.1°, and 63° were corresponds to crystal planes of (1 1 1), (0 0 2), (0 2 2), (3 1 1), and (2 2 2). The majority of these crystalline phases are monoclinic. The transition from tetragonal to monoclinic can occur with an increase in the calcination temperature which increases the crystallite size of the samples74. According to Fig. 1 for TiO2 sample, there is good agreement between the results of this study and the XRD pattern for the titanium dioxide phase reported in the literature75,76,77. The diffraction peaks at 2 thetha values of 25.32°, 37.90°, 48.09°, 54.10°, 55.15°, 62.85°, 68.99°, 70.49°, and 75.12° were belonged to crystal planes of (1 0 1), (0 0 4), (2 0 0), (1 0 5), (2 1 1), (2 0 4), (1 1 6), (2 2 0), (2 1 5)78. All the peaks observed in the diffraction pattern of TiO2 nanoparticles are in good agreement with anatase (JCPDS No. 00–001-0562). Figure 1 clearly shows magnetite formation with well-defined crystallinity in Fe3O4. All of the diffraction peaks are related to (2 2 0), (3 1 1), (2 2 2), (4 0 0), (4 2 2), (5 1 1), and (4 4 0) crystal planes and those were belonged to Fe3O4. The results confirmed the occurrence of inverse spinel structure in Fe3O4. The XRD peaks of impurities were not observed, which means that the synthesized Fe3O4 nanoparticles are pure79. Finally, in the XRD pattern of ZrO2/TiO2/Fe3O4 nanocomposite, the main peaks related to all three compounds were observed. The results showed that the sample has spinal reverse cube of Fe3O4 structure. The ZrO2 is amorphous phase and the phase of TiO2 is tetragonal (Anatase). The average crystallite sizes were calculated by Scherrer formula:

$${\text{D}} = \frac{{0.9 \times {\uplambda }}}{{{\upbeta } \times \cos {\uptheta }}}$$
(3)
Figure 1
figure 1

The XRD patterns of ZrO2, TiO2, Fe3O4, and ZrO2/TiO2/Fe3O4 nanocomposite.

where λ is X-ray wavelength, β is the full width at half maximum of the diffraction line and θ is the diffraction angle80. The average crystallite size of TiO2, ZrO2, Fe3O4 and ZrO2/TiO2/Fe3O4 was found to be 18.75 nm, 22.29 nm, 13.27 and 33.42 nm respectively. The most important cause of difference in particle size of synthesized samples can be the difference in their synthesis method81.

EDX analysis

EDAX analysis confirmed the presence of all elements, including Zr, Ti, O and Fe in the synthesized photocatalyst and there is no evidence of any other element. The inserted table in Fig. 2 presents an elemental composition of the photocatalyst. The results showed that the atomic ratio of Zr:Ti:Fe was 0.42:2.08:1.00. The synthesized nanocomposite had different peaks at 0.70, 6.39, and 6.92 keV which are related to Lα, Kα, and Kβ of Fe and 0.52 keV is Kα of oxygen. Peaks at 2.04 (Lα) and 2.26 (Lβ) keV are for zirconium. Fe3O4 particles are larger than TiO2 particles based on the results obtained.

Figure 2
figure 2

EDX spectrum. (Insert: Element analysis of synthesized nanocomposite).

SEM analysis

SEM analysis was used to determine the morphology and size of nanoparticles of ZrO2/TiO2/Fe3O4 nanocomposite (see in Fig. 3). In Fig. 3, ZrO2 and TiO2 nanoparticles are almost cubic and spherical respectively, while Fe3O4 does not have a specific shape.

Figure 3
figure 3

SEM image of ZrO2/TiO2/Fe3O4 nanocomposite.

BET analysis

Figure 4a and b show the porosity distribution curve and pore size distribution of ZrO2/TiO2/Fe3O4 nanocomposite. The specific surface area (SSA) was calculated using the N2 isotherms. The BET-SSA, the volume of pores, the average size of pores of the photocatalyst obtained were 280 m2/g, 0.92 cm3/g, and 42 nm respectively. The sample is mesoporous as the diameter of pores is larger than 2 nm. Hysteresis loop of types IV-H1 was obtained for the sample which is related to cylindrical and spherical pores in the sample82. In terms of pore size distribution, wide pore size distribution was observed, especially, pores with size larger than 3 nm had significant volume in the sample. It was found that the pore size larger than 3 nm is appropriate for the reactants penetration into the porous media of photocatalyst83,84.

Figure 4
figure 4

(a) N2 adsorption–desorption hysteresis and (b) pore size distribution of ZrO2/TiO2/Fe3O4 photocatalyst.

FTIR analysis

Figure 5a–d shows the FTIR analysis of ZrO2, TiO2, Fe3O4, and ZrO2/TiO2/Fe3O4 photocatalysts. As for ZrO2, the strong broad peak at 498–502 cm−1 region is attributed to the vibration mode of \({\mathrm{ZrO}}_{3}^{2-}\) groups. The peaks around 754 cm−1 are related to the Zr–O stretching vibrations in ZrO2. The IR at 1553 cm−1 attributed to stretching of O–H groups, which indicates the adsorbed moisture85. For TiO2 nanoparticles, TiO2 network bonds and deformation vibrations of stretching mode of Ti–OH peaks were observed at 483 cm−1 and 1623 cm−1 respectively. It can be related to the absorption of water on the TiO2 surface. Asymmetrical and symmetrical stretching vibration of hydroxyl groups (–OH) was observed at 3405 cm−1. The obtained results are consistent with those reported in the literature86,87. According to Fig. 5c, the stretching vibration of the O–H can be attributed to the absorption band 3444 cm−1. The peaks at 419 cm−1 and 589 cm−1 were attributed the stretching vibration of the Fe–O. The strong peaks in the 450–700 cm−1 range were attributed to stretching vibrations of Zr–O, Ti–O, and Fe–O in ZrO2/TiO2/Fe3O4 photocatalyst. The results confirm the presence of all three nanoparticles in the ZrO2/TiO2/Fe3O4 photocatalyst.

Figure 5
figure 5

FTIR spectra of (a) ZrO2, (b) TiO2, (c) Fe3O4, (d) of ZrO2/TiO2/Fe3O4 photocatalyst.

XPS analysis

For further investigation of the nature of the synthesized nanomaterial, we performed high-resolution X-ray photoelectron spectroscopy (XPS) on the synthesized ZrO2, TiO2 and Fe3O4 pure nanoparticles and the ZrO2/TiO2/Fe3O4 nanocomposite. The XPS spectra of pure and nanocomposite samples are shown in Fig. 6. Figure 6a and b show the XPS results of high-resolution Fe3O4 nanoparticles. Three components of the Fe–O bond can be seen in the XPS spectrum. After photoexcitation, the splitting of O1s at 531.6 eV indicates the formation of a Fe–O bond. The XPS peak of C1s at 292.6 eV and O1s at 531.6 eV indicate the formation of Fe–C and Fe–O bonds following particle photoexcitation (see Fig. 6a and b)88. Figure 6c and d show the XPS analysis of the pure TiO2 elemental composition. According to the XPS spectrum, elements Ti, C, and O are present on the surface of the TiO2 nanoparticles. Fe3O4 and TiO2 nanoparticle samples contained carbon resulting from carbon-based contaminants. The XPS peaks of Fig. 6c show C1s at 288.27 eV and O1s at 532.1 eV and Ti2p at 461.1 eV. Figure 6d shows the peaks of 458.5 eV and 464.2 eV, which correspond to Ti 2p3/2 and Ti 2p1/2, respectively. The peak position between Ti 2p3/2 and Ti 2p1/2 at 464.2 eV indicates the presence of Ti4+ oxidation state89,90. Figure 6e and f show the XPS spectrum of ZrO2 nanoparticles, which indicate the presence of relevant elements. The Zr3d level spectra of Fig. 6f show the Zr3d5/2 and Zr3d3/2 peaks at binding energies of 185.66 eV and 188.1 eV, respectively. The energy difference of 2.44 eV between the two peaks indicates the presence of Zr+491. The third suitable peak for the shoulder that appears at the base of Zr 3d3/2 can be attributed to the lack of oxygen, which can be due to under-coordinated Zr sites of very small ZrO2 nanoparticles92. XPS analysis was investigated to accurately determine the surface composition and chemical state of ZrO2/TiO2/Fe3O4 nanocomposite (As shown in Fig. 6g–k). As shown in Fig. 6g, the major peaks of Zr3d, C1s, Ti2p, O1s, and Fe2p are shown at 184.33, 282.59, 458.05, 530.18, and 708.37 eV, respectively. These results, in addition to confirming the presence of three nanoparticles ZrO2, Fe3O4 and TiO2, showed that ZrO2, Fe3O4 and TiO2 are mainly present as separate phases in the ZrO2/TiO2/Fe3O4 composite. Figure 6h shows that the binding energy of O1s appears at 530.08 eV, which proves the existence of oxygen in the crystal lattice (O2)93. In Fig. 6i, the dual peaks of Zr 3d with binding energies at 182.52 eV and 184.87 eV correspond to the chemical states Zr 3d3/2 and Zr 3d5/2, respectively, indicating zirconium in the + 4 oxidation state94. In addition, two peaks at 182.52 and 184.87 eV indicate the presence of Zr-Ti chemical bonds in the composites95. In Fig. 6j, the Ti 2p peaks at 458.84 eV and 464.58 eV correspond to the chemical states Ti 2p1/2 and Ti 2p3/2, respectively. Ti peaks confirm the presence of Ti4+ oxidation state in the nanocomposite. Meanwhile, the peak of 464.58 eV can be attributed to Zr-Ti chemical bonds96. The presence of chemical bonds Fe–O, Zr-O, Ti–O and Zr-Ti, Ti-Fe and Zr-Fe indicates a phase contact between Fe3O4, TiO2 and ZrO2. In Fig. 6k for Fe3O4, the major peaks at 710.96 eV and 724.59 eV are attributed to Fe3+ 2p3/2 and Fe3+ 2p1/2, respectively. The bond energy of Fe2+ 2p3/2 and Fe2+ 2p1/2 has a dual peak at 708.96 eV and 721.52 eV, respectively. Results of Fe3O4 XPS analysis are consistent with Fe2p spectrum97.

Figure 6
figure 6

XPS analysis of Nanoparticles (a) Fe3O4, (b) The O1s level spectrum, (c) TiO2, (d) The Ti 2p level spectrum, (e) ZrO2, (f) The Zr 3d level spectrum, and (g) Nanocomposite of ZrO2/TiO2/Fe3O4, XPS spectrum of (h) The O1s level (i) The Zr 3d level (j) The Ti 2p level and (k) The Fe 2p level.

EELS analysis

The electron energy-loss spectroscopy (EELS) analysis was used to identify the pure samples more accurately. The combination of EELS and statistical analysis can provide more information on the differentiation of Fe3O4 and Fe2O3 spinel structures. Figure 7a shows that the energy-loss peaks at 70.96 eV and 72.19 eV can only be attributed to Fe3O4 phase, since the expected value for gamma- Fe2O3 (70.2 eV) is significantly different. As shown in Fig. 7a, the EELS spectra of ZrO2 nanoparticles are obtained (obtained peaks for ZrO2 are 1.4, 14.8, 27.28 and 43.72 eV respectively). The synthesized ZrO2 nanoparticles can be proved according to the obtained peaks from the analysis. As shown in Fig. 7, the Ti structure in the EELS spectrum for Ti4+, indicates a lower oxidation state which has edges shift slightly towards the lower energy loss. Here, the blue curve is the fine structure of the Ti4+ state. EELS was obtained using a sub-nanometer probe size using the GIF2000 Filter.

Figure 7
figure 7

EELS spectrum for Structures of (a) Fe3O4, (b) ZrO2 and TiO2.

Photoluminescence spectra

The light absorption of photocatalysts significantly affects the activity of photocatalysts. Also, the spectrum of PL (Photoluminescence) and their intensity are closely related to its photocatalytic activity. Figure 8a–d shows the photoluminescence spectra (PL) of pure ZrO2, TiO2 and Fe3O4 samples and the ZrO2/TiO2/Fe3O4 nanocomposite at room temperature in the wavelength range of 300–600 nm with an excitation wavelength of 293 nm. As shown in Fig. 8a–c the pure ZrO2, TiO2 and Fe3O4 samples show significant PL signals at 376, 407, 478, and 480, 556, 509 and 543 nm, respectively. Among all samples, the TiO2 sample shows the highest intensity. The obtained PL spectrum for pure ZrO2 nanoparticles is almost similar to the results previously reported98. According to previous research99,100,101,102, the presence of these peaks in the visible range is probably due to the presence of oxygen vacancies, defects, surface states and other structural impurities. A high PL intensity of pure ZrO2 appears to indicate that the ZrO2 surface states are much lower, hence easy electron transfer can occur between VB and CB of ZrO2 even with a low-energy laser excitation source (325 nm)103. Additionally, when Fe3O4 and TiO2 are loaded with ZrO2 as ternary oxide catalysts, the PL intensity of ZrO2 decreases abruptly (Fig. 8d). The formation of a chemical interaction between pure oxides when they accumulate together (–Ti–O–Fe–), (–Ti–O–Zr–) and (–Fe–O–Zr–), as shown, has a profound effect on the photocatalytic properties104. A PL spectrum of the physically mixed pure ZrO2, TiO2, and Fe3O4 catalysts in different ratios further confirms the synergistic effect of the ZrO2/TiO2/Fe3O4 ternary system and the presence of (–Ti–O–Fe–), (–Ti–O–Zr–) and (–Fe–O–Zr–). The peaks shown at 403, 427, and 490 nm under the excitation wavelength of 293 nm for the ZrO2/TiO2/Fe3O4 nanocomposite must be due to the interference of trap states between the gaps, such as surface defects and oxygen vacancies (Fig. 8d)105. Preparation for solid samples (powder) was performed for PL (Photoluminescence Spectroscopy) analysis. The PL Spectroscopy was recorded by Avaspec-2048-TEC model spectrometer. The valence band (VB) and conduction band (CB) are shown in Fig. 8e. In this figure, the photocatalyst energy bands of Fe3O4/TiO2/ZrO2 are shown in (CB) and (VB). The VB determines the energy levels of electrons in the VB of an atomic structure. The combination of three metal oxides can be improved electromagnetic separation and narrowing of the photocatalyst band gap. In Fe3O4/TiO2/ZrO2 semiconductor, electrons migrate to CB whereas; positive holes are created on VB. The OH is formed through the reaction of charge carriers with adsorbed compounds on the photocatalyst surface. In Fe3O4/TiO2/ZrO2 nanocomposite, the electron–hole separation may occur between ZrO2 and TiO2. The surface energy of Fe3O4 for VB and CB was placed in TiO2 band gap and surface energy of TiO2 was placed in ZrO2 band gap (Fig. 8e). In the excitation of electrons from three catalysts, the majority of electrons migrate from CB of ZrO2 to CB of TiO2, then to CB of Fe3O4. As a result, electron–hole recombination is prevented in ZrO2 and occurs in Fe3O4.

Figure 8
figure 8

Photoluminescence (PL) spectra of (a) ZrO2, (b) TiO2, (c) Fe3O4 nanoparticles and (d) ZrO2/TiO2/Fe3O4 nanocomposite, (e) Energy level and electron–hole pair separation/transfer in ZrO2/TiO2/Fe3O4 nanocomposite.

Photocatalyst performance

The experimental work was designed and the obtained actual results, as well as predicted values, were provided in Table 3. Box–Behnken design for RSM was used for the experimental design. Statistical investigation of experimental data was performed using linear, two-factor interaction, quadratic, and cubic models. The results were given in Table 4. According to Table 4 and R2 values, the quadratic model was found the most accurate model for the prediction of experimental data in terms of naproxen removal. Its predicted R2 value was found to be 0.9901 which means the developed model equation is able to predict the results accurately. Therefore, the following quadratic polynomial model in terms of coded factors was proposed for investigation of naproxen degradation from pharmaceutical synthetic solution as a function of operating parameters:

$$\begin{aligned} & {\mathbf{Sqrt}}\left( {{\mathbf{NaproxenRemoval}}} \right) = - 0.2384{\text{A}} + 0.1918{\text{B}} - 0.1575C \\ & \quad + 0.{359}0{\text{D}} - 0.0{13}0{\text{AB}} - 0.0{\text{836AC }} \\ & \quad + 0.0{\text{471AD}} + 0.0{\text{192BC}} - 0.00{\text{91BD}} \\ & \quad - 0.0{2}0{\text{4CD}} - 0.{\text{1389A}} - 0.{\text{1168B}} - 0.{2}0{\text{35C}} + 0.{161}0{\text{D}} \\ \end{aligned}$$
(4)

where A, B, C, D are photocatalyst dose (g/L), time (min), solution initial pH, and initial concentration of naproxen (mg/L). The variables were defined at three levels including − 1, 0, and + 1.

Table 3 Operational parameters range in the designed experiments and actual and predicted results in terms of naproxen removal.
Table 4 Statistical investigation based on linear, two-factor interaction, quadratic, and cubic models.

Figure 9 illustrates the individual effects of operational parameters on naproxen removal. The contour lines represent lines of equal response and can be visualized as response contours two factors at a time. In this study, contour lines mean the performance of photocatalyst for naproxen removal at different operating parameters. The contour map reflects the cross-interaction between two variables by keeping the other variable constant. Interaction of initial pH and naproxen concentration for photocatalyst dose of 0.3 g/L and time of 60 min was shown in Fig. 9a. At a pH value of 6, increasing the initial concentration of naproxen from 10 to 30 mg/L led to the reduction of naproxen removal from 91.81 to 82.9%. Naproxen removal is reduced due to solution turbidity and a decrease in light absorption by the photocatalyst. Also, the amount of hydroxyl radical in the solution decreases. Furthermore, the photocatalyst surface is covered by pollutants with increasing its concentration from 10 to 30 mg/L which decreases photon penetration into the photocatalyst. Therefore, the photocatalyst was unable to generate enough electron–hole pairs, resulting in a reduced removal of naproxen. In the interaction between time and initial pH of the solution (Fig. 9b), the photocatalyst dosage and initial concentration of naproxen were considered 0.3 g/L and 20 mg/L respectively. Firstly, the efficiency of naproxen degradation was increased from 90.10 to 91.34% with increasing pH of the solution from 3 to 6, then, it was decreased to 84.9% at a pH value of 9. These changes are related to the oxidation potential and surface charge of the photocatalyst. The pH of the media can have a significant impact on the adsorption and desorption of pollutants on the photocatalyst surface.

Figure 9
figure 9

The 2D contour plots of RSM for investigation the degradation percentage of naproxen.

The amount of pKa is 4.15 for the naproxen. At pH values higher than 4.15, naproxen has a negative charge, otherwise, it has a positive charge. The neutral charge point of photocatalyst is 6. Therefore, it has a positive charge at pH below 6, whereas the surface charge of photocatalyst is negative at pH above 6. When the pH value is between 4.15 and 6, the naproxen and photocatalyst have opposite charges, so the adsorption of naproxen on the photocatalyst surface increases in this range. It is for this reason that maximum degradation occurs at pH 6 rather than pH 3 or 9. When the pH solution was 6, an increase in time from 30 to 60 min increased naproxen removal from 84.10 to 91.34%. The time and photocatalyst dosage interaction at constant initial pH and concentration of naproxen of 6 and 20 mg/L was shown in Fig. 9c. In Fig. 9c, and for a 60-min experiment run, there was an increase in naproxen degradation from 86.2 to 100% when the photocatalyst dosage was increased from 0.1 to 0.5 g/L. Photocatalyst dosage had a significant effect on naproxen degradation, increasing the number of available active sites for the generation of hydroxyl radicals. However, too much photocatalyst in the system can reduce naproxen degradation as a result of agglomeration of photocatalyst nanoparticles. The reduction in active site of the photocatalyst resulted from agglomeration. It was found that a decrease in pH can increase naproxen degradation (Fig. 9d), and the greatest degradation was obtained at pH 3. The solution pH had a complicated effect on the photocatalytic oxidation reaction. The optimum pH value is highly dependent on the type of pollutant and point of zero charges (PZC) of the photocatalyst. According to Fig. 10, it is 6 for the synthesized photocatalyst. At pH = pHPZC, the surface charge is neutral. The surface charge can be positive or negative at pH < pHPZC and pH > pHPZC. The amount of adsorption is highly dependent on the surface charge of photocatalyst and pollutant and it can be controlled by a change in solution pH.

Figure 10
figure 10

Point of zero charge ZrO2/TiO2/Fe3O4 photocatalyst.

The analysis of variance (ANOVA) results obtained for the present model are summarized in Table 5. The results suggested that a quadratic model is significant because of its high F-value (431.34) and very low p-value (< 0.001). The calculated higher F-value and lower p-value for the photocatalyst dosage (D factor) in comparison with other factors indicated that the photocatalyst dosage is the most important parameter in the system. The results in Table 5 showed that the proposed statistical model is accurately fitted to experimental data. The accuracy of the proposed model should be investigated in detail. Figure 11 shows a linear relationship between experimental data and predicted values in terms of naproxen removal and it confirms the accuracy of the proposed model as all the data accumulated around a 45-degree line. The normal probability plot of the residuals was shown in Fig. 11b and it can be clearly seen a linear scattering of modeling data. The linear scattering means normal distribution of errors in a defined matrix for experimental design. Therefore, the probability of random error intervention and effect of the sequence of experiments is considerably decreased in the proposed model.

Table 5 ANOVA results for the quadratic model.
Figure 11
figure 11

(a) The relationship of predicted and actual values of the RSM model for naproxen removal; (b) the externally studentized residuals versus normal % probability distribution.

Optimization using RSM

An optimization was performed in order to find the optimal operating conditions for the removal of naproxen completely from pharmaceutical synthetic solutions. According to the proposed model, the following independent operating parameters are required for complete removal of naproxen (101.92%): initial naproxen concentration = 18.95 mg/L, initial pH value = 4.55, photocatalyst dosage = 0.49 g/L, time = 74.31 min. Figure 12 illustrates different operating conditions that can be used to achieve complete degradation of naproxen.

Figure 12
figure 12

A range of independent variables of pH, photocatalyst dosage, time, and initial naproxen concentration.

Reusability ZrO2/TiO2/Fe3O4 photocatalyst

The regeneration and re-use of the used or spent photocatalyst is very critical for determining the applicability of the process applied. The used photocatalyst was separated from the synthetic solution using 1.3 Tesla magnetic. Then, it was used for the treatment of pharmaceutical synthetic solution as given in Fig. 13. As can be seen in Fig. 13, the degradation efficiency only display partial reduction after seven cycles for degradation of naproxen, indicating excellent reusability of the synthesized photocatalyst as after 7 runs, its performance for naproxen degradation was decreased only 12%. Additionally, the photocatalyst was placed in distilled water under UV light for 12 h in order to regenerate it. After doing the regeneration process, the photocatalyst was able to degrade the naproxen by about 98.4%. However, after three regenerations, the activity of the photocatalyst decreased by 8.4%. The decrease in performance of photocatalyst may be related to the blocking of active pores due to precipitation of non-sensitive chemicals to light or destroying of effective nanoparticles during the recovery process. Each experiment was replicated three times and an error bar was shown in Fig. 13.

Figure 13
figure 13

Reusability and regeneration of ZrO2/TiO2/Fe3O4 photocatalyst for naproxen degradation.

Analysis study of naproxen removal kinetics

The removal of naproxen using heterogeneous photocatalyst is divided into two main stages: physical adsorption reaction and chemical reaction. In order to describe the photocatalytic degradation rate of naproxen by plotting ln(C0/C) versus time (t), at different concentrations, the Langmuir–Hinshelwood (LH) kinetic model was used106:

$$ln\frac{{C}_{i}}{C}=k.t$$
(5)

where Ci(mg/L), the initial concentration of naproxen and C(mg/L), the concentration at time (t) after irradiation, and k is a pseudo-first-order rate constant. As shown in Fig. 14, the pseudo-first-order rate constant was determined based on a straight-line slope. According to the results of Fig. 14b, the maximum reaction rate at the initial concentration of 5 mg/L naproxen is 0.0514 min−1, which is about 2 times higher than the obtained reaction rate at the initial concentration of 30 mg/L naproxen. The obtained results in Fig. 14b show that reaction rates decrease with increasing concentration. The naproxen absorbed amount qe (mg/g) by ZrO2/TiO2/Fe3O4 nanocomposite was calculated using the following equation (Eq. (6)):

$${q}_{e}=\frac{\left({C}_{i}-{C}_{e}\right).V}{m}$$
(6)

where Ci and Ce are the initial and equilibrium concentrations of naproxen (mg/L), respectively. The volume of naproxen solution (ml) is V and the mass of ZrO2/TiO2/Fe3O4 nanocomposite (mg) is m. The following equation was used to calculate the percentage of naproxen adsorption (%) (Eq. 7):

Figure 14
figure 14

(a) The effect of initial concentrations on NPX removal(%), (b) The effect of initial concentrations of NPX on photo degradation, (c) The initial reaction rate (r0) as a function of NPX initial concentration (C0); (d) L–H model of photocatalytic NPX degradation by ZrO2/TiO2/Fe3O4 ; (e) The effect of different initial concentrations on the NPX photo degradation rate constant.

$$Adsorption (\%)=\frac{\left({C}_{i}-{C}_{e}\right).V}{m}$$
(7)

As shown in Fig. 14 when the initial concentration of naproxen was increased from 5 to 30 mg/L, the initial photodegradation rate (r0) also gradually increased from 0.26 to 0.77 mg/L. It was shown that naproxen photocatalytic degradation occurs on ZrO2/TiO2/Fe3O4 nanocomposite surfaces and that the rate of photo degradation increases as a function of increasing of adsorption. As the initial concentration of naproxen increases, the coverage of naproxen molecules on the surface of ZrO2/TiO2/Fe3O4 nanocomposite also increases accordingly. As a result, the electron transfer efficiency of naproxen molecules to the adsorbed surface and the charge produced by the light increases, which leads to an increase in the initial optical decomposition rate (r0). As a result, the electron transfer efficiency of naproxen molecules, which leads to an increase in the initial photodegradation rate (r0), increases with increasing absorbed surface and the produced charge by light. For different initial concentrations, the kinetic constant of naproxen photo degradation gradually decreased (from 0.0514 to 0.0255 min−1), while the R2 correlation coefficient also decreased from 0.9961 to 0.9817. The relationship between the reaction rate (k) and the initial concentration of the substrate during the photocatalytic process can be generally explained by the following experimental formula (Eq. 8):

$$k=a{[NPX]}^{n}$$
(8)
$$ln k=ln a+nln[NPX]$$
(9)

where n is the correlation index and [NPX] is the initial concentration (NPX) (mg.L−1).

Linear regression was used to analyze the relationship between the kinetic constant of NPX photo degradation and its initial concentration (5–30 mg/L). Figure 14 shows that the relationship between reaction rate k and NPX concentration is as follows:

$$ln k = ln 0.0196 + 0.2074.ln\left[ {NPX} \right]\quad \quad \quad \quad ({\text{R}}^{{2}} = 0.{9992})$$
(10)

The results showed that the adsorption of naproxen on the surface of ZrO2/TiO2/Fe3O4 nanoparticles is clearly time-dependent. As shown in Fig. 14a most naproxen removal occurred within the initial 50 min, and after 50 min, naproxen removals occurred almost in the flat part of the graph. The highest percentage of naproxen removal is at the initial concentration of 5 mg/L of solution. In the initial 50 min, two mechanisms were involved in the removal of naproxen: the free active sites at the adsorbent surface, and the generation of hydroxyl ions. Subsequently, a slow rate of naproxen removal was observed.

Different kinetic models were investigated to analyze the kinetic data and determine the kinetic mechanism of naproxen adsorption on the surface of ZrO2/TiO2/Fe3O4 nanocomposite which is shown in Table 6.

Table 6 Equations of adsorption kinetic models for naproxen adsorption on ZrO2/TiO2/Fe3O4 nanocomposite.

Elovich model shows less linearity in the regression coefficient R2; which was found to be 0.9202, On the other hand, the correlation coefficient value for a Langmuir–Hinshelwood (LH) kinetic model was obtained 0.9992 for NPX and greater than all other adsorption kinetic models. The calculated qe value was found to be 26.4 mg/g for NPX, which was very close to the obtained experimental values (shown in Table 6). According to the obtained results, it is expected that NPX and its degradation intermediates may be further degraded by reactive species, thus leading to ring openings and eventually oxidation to CO2 and H2O. As can be seen in Fig. 15, the possible degradation pathways of NPX are proposed based on the identification of intermediates and mineralization results. The photocatalytic degradation of NPX by ZrO2/TiO2/Fe3O4 mainly refers to three main pathways including decarboxylation and hydroxylation39. Three possible degradation pathways through oxidation processes are shown in Fig. 15. In the oxidation pathway I, NPX degradation was initiated by the electrophilic additive interaction between the naphthalene ring of NPX and ·OH114,115,116. In pathways II and III, NPX oxidation was performed by h+ and ·O2− and carbon-based radical species were formed by decarboxylation117. All produced intermediates during the process were decomposed by ring-opening reactions to malic acid, succinic acid, propionic acid and acetic acid, and finally mineralized to CO2 and H2O39,118,119.

Figure 15
figure 15

Photo degradation reaction mechanism of NPX by ZrO2/TiO2/Fe3O4.

In order to confirm mineralization, we investigated total organic carbon (TOC) in the degradation of naproxen at ambient temperature and pH = 3. The amount of TOC was decreased with increasing irradiation time (Fig. 16). In this study, the mineralization of naproxen is confirmed using ZrO2/TiO2/Fe3O4 photocatalysts. TOC removal was obtained 87% after 90 min irradiation. Naproxen may be oxidized to CO2, H2O, and some small molecules, according to TOC results.

Figure 16
figure 16

Total organic carbon (TOC) in naproxen wastewater as a function of time and the ZrO2/TiO2/Fe3O4 photocatalytic activity.

As shown in Table 7, in comparison with previous studies, the synthesized photocatalyst in this study had the highest naproxen removal efficiency. The synthesis of ternary nanocomposites confirmed the excellent synergistic effect of these three types of nanoparticles on the photocatalytic process. Based on the Table 7, the synthesized photocatalyst has high specific surface area. In addition, it’s proper capability in acidic environment increases efficiency and absorption over time for the removal of naproxen at low dosage of catalyst in comparison with other similar synthesized photo catalysts.

Table 7 Comparison of naproxen removal efficiency in the presence of synthesized photocatalyst under optimum process conditions.

Conclusion

In summary, we synthesized a ternary ZrO2/TiO2/Fe3O4 nanocomposite system using a solid-state dispersion method. Furthermore, its photocatalytic activity towards naproxen degradation was investigated. The effect of operating parameters including initial naproxen concentration, initial pH, photocatalyst dosage, and time on the degradation of naproxen was investigated. Characterization results confirmed the formation of the ternary nanocomposite. The existence of cylindrical and spherical pores in the sample was proved because its N2 adsorption–desorption hysteresis followed IV-H1 type hysteresis. Based on optimization results using the RSM method, the optimal conditions for the complete removal of naproxen were determined as initial naproxen concentration of 18.95 mg/L, initial pH of 4.55, photocatalyst dosage of 0.49 g/L, and time of 74.31 min. Reusability results showed 12% reduction in naproxen degradation after 7 runs. It was found that Langmuir–Hinshelwood's (LH) kinetic model was linear. The regression coefficient (R2) was obtained 0.9992 and it was greater than all other adsorption kinetic models.