Raw sepiolite was purchased from Henan province, and the main chemical compositions analyzed by XRF were 54.36% SiO₂, 35.6% MgO, 5.67% CaO and 1.36% Fe₂O₃. Hydrochloric acid (HCl), iron (III) nitrate nonahydrate [Fe(NO₃)₃⋅9H₂O], zinc chloride (ZnCl₂), ammonia (NH₃⋅H₂O), ethanol (CH₃CH₂OH), silver nitrate standard solution (AgNO₃, 0.1 mol/L), tetracycline hydrochloride (TCH), butyl alcohol (TBA), P-benzoquinone (BQ) and ammonium oxalate (AO) were analytical reagent and used without further purification.

1.3629 g of ZnCl₂ and 8.08 g of Fe(NO₃)₃⋅9H₂O were dissolved in 100 ml deionized water, and a certain amount of sepiolite which were prepared by an acid treatment were added into the solution. Next, the pH of suspension was adjusted to 11 by adding aqueous ammonia dropwise. After aging for 12 h at room temperature, the precursor slurry was washed with ethanol and deionized water until the presence of chloride ions cannot be detected with silver nitrate standard solution. Then the filter cake was calcined in a muffle furnace for 3 h at 600°C. Finally, the ZnFe₂O₄/sepiolite composite (ZF-Sep) was obtained, and the schematic diagram was shown in Figure 1. On the other hand, pure ZnFe₂O₄ were also prepared by the same process. Samples were prepared with initial mass ratios of ZnFe₂O₄ to sepiolite nanofibers having values of 1:3, 1:2, 1:1, 2:1, 3:1, and labeled as ZF-Sep-13, ZF-Sep-12, ZF-Sep-11, ZF-Sep-21, ZF-Sep-31, respectively.

Element analysis was carried out by ZSX Primusll X-ray fluorescence spectrometer (XRF). X-ray diffraction (XRD) patterns were employed to analyze the phase composition of samples by an X’Pert MPD dilatometer with CuKα radiation (40 Kv, 40 mA and λ = 1.54180 Å). The scanning was made in the 2θ range of 5–90° with a scanning speed of 12/min at room temperature. Scanning electron microscopy (SEM, JSM 7610F) and transmission electron microscopy (TEM, JEM-2010FEF, JEOL) were employed to observe the morphologies of the samples. Infrared radiation spectra of the as-prepared composites were obtained by a Fourier transform-infrared (FTIR) test spectrometer (Bruker VERTEX 80V) in the range of 4,000–400 cm⁻¹ using KBr pellets. The X-ray photoelectron spectroscopy (XPS) measurements were performed on ESCALAB 250Xi (United States, Thermo Fisher Scientific) using a monochrome Al Kα (150 W, 20 eV pass energy, and 500 μm beam spot size). The magnetic property of the samples was measured by a vibrating sample magnetometer (VSM, Lakeshore VSM 7407) at room temperature. The surface area of the samples was tested by the physicochemical adsorption analyzer (United States, autosorb iQ). Diffuse reflectance ultraviolet-visible spectra (UV-vis DRS) were measured on a Shimadzu UV-1800 spectrophotometer.

The photocatalytic performance of the as-prepared samples was evaluated by the removal efficiency of TCH under visible light irradiation. 0.1 g of catalyst was dispersed into 100 ml of TCH solution (20 mg/L). Before the suspension was subjected to irradiation by a 300 W Xe lamp (λ > 420 nm), stirring the produced suspension in the dark for half an hour to reach the adsorption/desorption equilibrium. Then, 3 ml of the suspension were extracted every 30 min and passed through a 0.22 micron filter membrane to remove the catalysts. The absorbance values at 357 nm of the filtrate were measured by a TU-1800 ultraviolet visible spectrophotometer. The removal efficiency can be calculated according to the following equation: R E % = ( C 0 − C t ) C 0 × 100 %  (1) Where RE% represents the removal efficiency of catalyst, C ₀ represents the TCH concentration at the beginning, and C _t represents the TCH concentration at a certain time t.

To detect the active species generated in the degradation process, the scavengers including butyl alcohol (TBA; 5 mmol/L), p-benzoquinone (BQ; 5 mmol/L), and ammonium oxalate (AO; 5 mmol/L) were added into the solution of TCH, respectively. The photocatalytic process was the same as that described above.

The phase composition of samples was examined by XRD analysis. As shown in Figure 2, seven diffraction peaks (2θ) at 18.25°, 29.66°, 35.30°, 42.83°, 52.94°, 56.71° and 62.35° in curve of ZnFe₂O₄ correspond to the planes (111), (220), (311), (400), (422) (511) and (440) of ZnFe₂O₄, respectively. It confirms that single phase ZnFe₂O₄ (JCPDS No. 22-1012) with cubic spinel structure were synthesized successfully (Ma et al., 2019; Madhukara Naik et al., 2019). The characteristic peaks of sepiolite gradually decreased with the increase of the ZnFe₂O₄ content in the ZF-Sep composites, whereas the peaks intensity of ZnFe₂O₄ strengthened gradually, indicating that the co-existence of ZnFe₂O₄ and sepiolite in these composites. The decrease and broadening of diffraction peaks of ZnFe₂O₄ was derived from its dispersing in the surface of sepiolite. The decrease of sepiolite peak intensity was attributed to its imperfect crystalloid by disconnecting the fiber unit and the phase change of sepiolite to talc at the sintering temperature of 600°C (Xu et al., 2010).

The micromorphology of the ZnFe₂O₄ and ZF-Sep-11 composite were characterized by SEM and TEM. In Figures 3A,C, the images show that ZnFe₂O₄ sample was consisted of irregular nanoparticles with a size of about 20–200 nm. The existence of relatively large particles was attributed to the high specific surface energy of the nanoparticles causing serious agglomeration. As seen in Figures 3B,D, lots of small and irregular particles (about 20 nm) attached to the surface of sepiolite fibers, and the high resolution image (Figure 3E) displayed that the interface of ZnFe₂O₄ possessing obvious lattice fringes [d (311) = 0.25 nm] closely connected with the interface of sepiolite which shows no obvious lattice fringes due to the low crystallinity. Consistent with the XRD results, SEM and TEM analysis also confirmed the successful synthesis of the composite, and the introduction of sepiolite fibers largely alleviated the agglomeration of ZnFe₂O₄. Figure 4 shows the FTIR spectra of the sepiolite, ZnFe₂O₄ and ZF-Sep-11 composite. In the spectra of sepiolite, the bonds at 3,684–3,567 cm⁻¹ and 664 cm⁻¹ corresponded to the stretching and bending vibrations of Mg-OH in the Mg-O octahedral sheet. The bonds at 1,020 and 462 cm⁻¹ were attributed to the stretching vibrations of Si-O bond in the Si-O-Si groups of the Si-O tetrahedral sheet (Zhang et al., 2014; Zhu et al., 2012.). There were two obvious peaks at 535 and 450 cm⁻¹ in the spectra of ZnFe₂O₄, which could be ascribed to the stretching vibrations of the Zn-O bond and Fe-O bond in the spinel structure (Li J. et al., 2019; Mohan et al., 2020; Wang P. et al., 2019.). As shown in the spectra of ZF-Sep-11, the stretching vibrations of Si-O bond at 1,020 cm⁻¹ shifted to 1,026 cm⁻¹ and the stretching vibrations of Zn-O and Fe-O bands at 535 and 450 cm⁻¹ shifted to 566 and 444 cm⁻¹, which was possible ascribed to the interaction between ZnFe₂O₄ and sepiolite nanofibers (Wang W. et al., 2019; Xu et al., 2017.).

The XPS method was employed to the ZnFe₂O₄ and ZF-Sep-11 composite sample to investigate its elemental composition and chemical states. As illustrated in Figure 5A, the survey spectrum of ZnFe₂O₄ shows the signal peaks of Fe 2p, Zn 2p, O 1s, indicating that Zn, Fe and O elements in the samples. Compared with ZnFe₂O₄, the appearance of Mg 1s and Si 2p indicated the introduction of sepiolite (Figure 5D). It is worth noting that the signal peaks of C 1s in the XPS survey spectrum are mainly caused by the external C impurities of XPS instrument. In Figure 5B, the O 1s spectrum of ZnFe₂O₄ could be divided into two peaks at approximately 529.7 and 531.2 eV, corresponding to the lattice oxygen and the oxygen absorbed on the surface, respectively (Wang S. et al., 2020). As shown in Figure 5E, the peak at 530.3 eV represented the lattice oxygen of ZnFe₂O₄, and that at 531.8 and 532.4 were attributed to the O atom of the -OH and Si-O-Si bond from sepiolite nanofibers. In the Fe 2p spectrum of ZnFe₂O₄ (Figure 5C), the peaks at 724.2 and 710.6 eV represented the Fe³⁺, and 709.4 eV were attributable to the Fe²⁺ (Li Y. et al., 2019; Wang S. et al., 2020). Compared with ZnFe₂O₄, the peak positions of Fe³⁺ (725.8 and 712.2 eV) and Fe²⁺ (724.2 and 710.6 eV) had a certain shift, and the ratio of Fe³⁺ to Fe²⁺ was reduced (Figure 5F), which could be ascribed to the electron transfer and ion exchange between ZnFe₂O₄ and sepiolite nanofibers. Therefore, the sepiolite nanofibers in the composite might act as a good medium for the migration of photogenerated carriers in the reaction process, thereby reducing the recombination rate of photogenerated electrons and holes to increase the photocatalytic efficiency (Liu et al., 2015).

The nitrogen adsorption-desorption isotherms of sepiolite, ZnFe₂O₄ and ZF-Sep-11 composite were shown in Figure 6A, and the isotherms were in the shape of type IV, which indicated a typical of mesoporous materials. The result was further confirmed by the corresponding pore size distribution in Figure 6B. The specific surface area, total pore volume and average pore size of ZnFe₂O₄ and ZF-Sep composites with different loadings of ZnFe₂O₄ were summarized in Table 1. With the increase of the ZnFe₂O₄ loadings, the specific surface area of the composites showed a trend of first increasing and then decreasing, but all the composites were larger than pure ZnFe₂O₄. The optimal sample was ZF-Sep-11 composite, and its specific surface area was 138.3 m²g⁻¹. The nitrogen adsorption-desorption isotherms also demonstrated that the introduction of sepiolite nanofibers improved the agglomeration of ZnFe₂O₄, which increased the contact area with the target degradation product, thereby improved the photocatalytic performance.

The optical properties of the as-prepared samples were analyzed by UV-vis reflectance spectroscopy to evaluate the light absorption ability. As shown in Figure 7A, ZnFe₂O₄ and ZF-Sep composites presented significant absorbance in the 450–700 nm wavelength range. The band gap of ZF-Sep-11 composite could be estimated to be 1.52 eV, which was a little smaller than that of ZnFe₂O₄ (1.86 eV) (Figure 7B). In comparison with ZnFe₂O₄, ZF-Sep-11 composite showed the narrower band gap and higher light absorption, which could exhibit positive influence on the removal efficiency of target antibiotic in the visible light range.

The magnetic properties of the ZnFe₂O₄ and ZF-Sep-11 composite were measured by a vibrating sample magnetometer (VSM) with an applied magnetic field between −20,000 and 20,000 Oe at room temperature. Figure 8 shows the plot of magnetization versus applied field with a small hysteresis loop which indicates that the samples display typical ferromagnetic (soft magnetic). The saturation magnetization (M_s) of ZnFe₂O₄ and ZF-Sep-11 composite were 51.693 and 34.780 emu/g, respectively. The decreasing of M_s mainly derives from the addition of non-magnetic material sepiolite. Due to the typical ferromagnetic, the catalyst could be efficiently removed from the aqueous solution of reaction mixture by an external magnet.

The photocatalytic performance of the as-synthesized samples was evaluated by degrading TCH under visible light (λ ≥ 420 nm). The measured removal efficiency of the samples under different preparation conditions were depicted in Figure 9. As can be seen in Figure 9A, the removal efficiency of TCH solution was almost negligible when there was no catalyst and single sepiolite. For ZnFe₂O₄ and the composites, the decrease in the concentration of the TCH solution in the first 30 min in the absence of light may be due to the influence of the Fenton system formed by the addition of H₂O₂. The removal efficiency of tetracycline hydrochloride was 56.7% for ZnFe₂O₄ within 3 h. All of the composites exhibited superior removal efficiency for TCH compared with the single ZnFe₂O₄. Among these composites, ZF-Sep-11 showed the optical performance, and the removal efficiency of TCH reached 93.6% within 3 h. Figure 9B shows the reaction kinetics of the as-synthesized samples, in which the experimental data were in accordance with the pseudo first-order kinetic equation: ln ( C 0 / C ) = kt (3) Where C ₀ is initial concentration of TCH solution, C is the concentration of tetracycline hydrochloride at reaction time t, and t is the reaction time and k is the fitted kinetic rate constant. The values of kinetic rate constant of sepiolite, ZnFe₂O₄, ZF-Sep-31, ZF-Sep-21, ZF-Sep-11, ZF-Sep-12 and ZF-Sep-13 were 0.000248, 0.00293, 0.01057, 0.00686, 0.01504, 0.01188 and 0.00771 min⁻¹, respectively. ZF-Sep-11 showed the highest kinetic rate constant, which is about five times higher than that of signal ZnFe₂O₄.

Different amounts of ZF-Sep-11 composite were used in the catalytic experiment to explore the effect of the catalyst content on the removal efficiency of TCH. The dosage of catalyst is set to 0.5, 1.0 and 1.5 g/L (the ratio of catalyst to TCH solution). In Figure 10A, when the dosage of catalyst was 0.5 and 1.5 g/L, the removal efficiency was 66.8 and 86.2% at 3 h, respectively, which were lower than the removal efficiency of 1.0 g/L (92.3%). The result means that too little catalyst dosage will cause the reduction of removal efficiency, because a small amount of active free radicals were generated. However, when an excessive amount of the catalyst was dispersed in the TCH solution, a small amount of light can reach their surface due to the influence of turbidity and scattering effect. The less exposed area under light may result in a decrease in overall catalytic efficiency.

Figure 10B showed the removal efficiency at different initial concentrations of TCH solution. The removal efficiency was 94.7, 92.2, 87.9, 82.4 and 75.9% in 3 h for 10, 20, 30, 50 and 80 mg/L of TCH solution, respectively. As the concentration increases, the removal efficiency of TCH gradually decreases. It could be attributed to the fact that the active sites on the surface of the catalyst are blocked in a high-concentration tetracycline solution.

In order to improve the ability to remove TCH, the amount of H₂O₂ added has been optimized. In Figure 10C, compared with the addition of 1 mM, when the addition of H₂O₂ was 0.5 and 1.5 mM, the removal efficiency were slightly reduced. Low H₂O₂ addition produces little free radicals. However, the excess H₂O₂ molecules will act as a quencher of OH to generate perhydroxyl (·OOH) radicals and compete with OOH to generate H₂O and O₂ (Su et al., 2012). · OH  + H 2 O 2 → H 2 O + · OOH (4) · OH  + · OOH → H 2 O + O 2 (5)

In order to determine the main active species in the removal of TCH for ZF-Sep composite, free radical trapping experiments were implemented. BQ, IPA and AO were added as scavengers for O₂ ⁻, ·OH and h⁺, respectively. As depicted in Figure 11, the removal efficiency of TCH was 93.2% without any scavengers. After adding AO, there was no obviously decline in the removal efficiency of TCH (81.4%). However, the addition of TBA and BQ decreased the removal efficiency of TCH to 34.8 and 61.9%, respectively. The above results indicate that O₂ ⁻ and OH were the main active species in the removal process.

The liquid chromatography-mass spectroscopy (LC-MS) was used to analyze the possible intermediates that produced during the TCH degradation process to reveal the possible TCH degradation pathway. The LC-MS spectra displayed the formation of intermediate products with m/z values of 445, 419, 365, 353, 279, 218, 173, and 140 under visible light irradiation. According to the above results, the possible TCH degradation paths were proposed as shown in Figure 12. Firstly, TCH dissociates into tetracycline (TC) corresponding to m/z 445 in the aqueous solution (Lu et al., 2021). Due to the produced active species easily attack the amine group, hydroxyl group and methyl group in TC, the mass spectra corresponding to m/z 419 and m/z 353 were identified as the products formed from detachment of these groups of TC molecule. Secondly, the ring-opening products (m/z 365, m/z 281 and m/z 218) were assigned as the further oxidation products. Carboxyl group was detached from the ring-opening product (m/z 270) and then the intermediate product (m/z 140) was formed from the demethylation reaction (Pang et al., 2018; Li Z. et al., 2019.). Finally, these intermediate products were mineralized into CO₂ and H₂O via ring-opening reactions (Wu et al., 2021.).

On the basis of the above analysis, a possible mechanism was shown in Figure 13. The loading of ZnFe₂O₄ on sepiolite nanofibers significantly improves its agglomeration phenomenon, which made more active sites in the surface of ZnFe₂O₄ were exposed, thereby improving its catalytic activity. Under visible light, the catalyst was activated to generate electron-hole pairs (Eq. 6). The sepiolite nanofibers might act as a good medium for the migration of photogenerated carriers to reduce the recombination rate of photogenerated electrons and holes. The holes were captured by OH⁻ or H₂O to generate OH, and O₂ ⁻ radicals were generated by trapping electrons for O₂ (Eqs. 7–9). In the presence of H₂O₂, it was more likely to trapping electrons to generate OH than O₂ (Eq. 10). Meanwhile, Fe³⁺ active sites were reduced by electrons to produce Fe²⁺ active sites which will activate H₂O₂ to produce regenerated Fe and new OH (Eqs. 11–12). Moreover, the generated Fe³⁺ reacted with OH⁻ to formed Fe²⁺ and OH (Eq. 13). Finally, TCH was degraded by the generated OH, ·O₂ ⁻ and a small amount of h⁺ (Eq. 14) (Li J. et al., 2019). Therefore, the synergistic effect of photochemical and catalytic reaction exists in the system of Vis-light/ZnFe₂O₄/sepiolite/H₂O₂. catalyst + h ν → catalyst ( e − + h + ) (6) h + + H 2 O → · OH + H + (7) h + + OH − →   · OH (8) e − + O 2 →   · O 2 − (9) e − + H 2 O 2 →   · OH + OH −   (10) e − +   Fe 3 + →   Fe 2 +   (11) Fe 2 + + H 2 O 2 → Fe 3 + + · OH + OH − (12) Fe 3 + + H 2 O 2 →   Fe 2 + + · OOH + H + (13) h + ,   · OH ,    · O 2 −   +   TCH → CO 2 + H 2 O (14)

In order to explore the reusability and stability of the catalyst, four cycles of experiments were carried out. The degradation plots are shown in Figure 14, removal efficiency for the first cycle is 84.5%, second cycle is 81.2%, third cycle is 80.5%, and for the fourth cycle is 79.5%. It observed that there is no significant reduction in the removal efficiency. The above results show that the prepared catalyst has good recyclability and stability.