Removal of Organic Dyes from Water and Wastewater Using Magnetic Ferrite-Based Titanium Oxide and Zinc Oxide Nanocomposites: A Review

Heterogeneous photocatalysis using titanium dioxide (TiO2) and zinc oxide (ZnO) has been widely studied in various applications, including organic pollutant remediation in aqueous systems. The popularity of these materials is based on their high photocatalytic activity, strong photosensitivity, and relatively low cost. However, their commercial application has been limited by their wide bandgaps, inability to absorb visible light, fast electron/hole recombination, and limited recyclability since the nanomaterial is difficult to recover. Researchers have developed several strategies to overcome these limitations. Chief amongst these is the coupling of different semi-conductor materials to produce heterojunction nanocomposite materials, which are both visible-light-active and easily recoverable. This review focuses on the advances made in the development of magnetic ferrite-based titanium oxide and zinc oxide nanocomposites. The physical and magnetic properties of the most widely used ferrite compounds are discussed. The spinel structured material had superior catalytic and magnetic performance when coupled to TiO2 and ZnO. An assessment of the range of synthesis methods is also presented. A comprehensive review of the photocatalytic degradation of various priority organic pollutants using the ferrite-based nanocomposites revealed that degradation efficiency and magnetic recovery potential are dependent on factors such as the chemical composition of the heterojunction material, synthesis method, irradiation source, and structure of pollutant. It should be noted that very few studies have gone beyond the degradation efficiency studies. Very little information is available on the extent of mineralization and the subsequent formation of intermediate compounds when these composite catalysts are used. Additionally, potential degradation mechanisms have not been adequately reported.


Introduction
Nowadays, concern around efficient management of water use has become topical, with interest not only limited to agricultural and industrial sectors but also attracting public health and sustainable economic development proponents.
The wide range of anthropogenic activities that use water results in the generation of highly toxic effluents, which are rich in organic pollutants, rendering them unsuitable for reuse in agricultural activities and human consumption. As a result, water decontamination has become the focus of attention for several studies.  [12]. Unit cell structure of (b) normal spinel ferrite, and (c) inverse spinel ferrite [25]. Republished with permission from Elsevier.
Due to the small band gap energy of ferrites, which makes them effective under absorption of visible light irradiation, they are extremely suitable for the removal of organic pollutants in water and wastewater treatment processes [22,23].

Methods of Synthesis of Magnetic Spinel Ferrites
Synthesis methods play an important role in the development of magnetic nanoparticles as this controls the electrical, optical, and magnetic properties of the material [15].
Co-precipitation requires careful monitoring of pH in order to obtain pure spinel ferrites [25]. Advantages associated with this method include low cost, short synthesis time, high product yield, and production of uniformly sized particles [45].
For example, El-Okr et al. [46] synthesized magnetic CoFe 2 O 4 using the co-precipitation method and obtained crystallites between 11 and 45 nm in size, with saturation magnetization ranging from 5 to 67 emu/g. The authors reported that the difference in crystallite size and saturation magnetization (Ms) values was associated with the variation of parameters such as pH and calcination temperature.
The hydrothermal synthesis method enables particle size control and flexibility in terms of surface modification. It is based on the wet-chemical synthesis; typically, this occurs in sealed reactors or autoclaves at high vapor pressures (from 0.3 to 4 MPa) and elevated temperatures (130 to 250 • C) [47,48].
Some noteworthy advantages of this method include low temperature for synthesis, high purity, simple reactions, cost-effectiveness, and good dispersibility of the MNPs [49]. For instance, Zhao et al. [41] prepared cobalt ferrite using the hydrothermal method. The resultant material had 70 nm crystallites with a saturation magnetization (Ms) of 86 emu/g.
The sol-gel method is extensively used for the synthesis of spinel ferrites [50][51][52][53][54][55]. The process involves the transition of a system from a liquid phase (sol) to a solid phase (gel), through chemical reactions such as hydrolysis and condensation polymerization of the metallic precursors [25]. Thus, its widespread acceptance is driven by the low cost associated with the method, better homogeneity, composition control, and narrow particle size distribution at relatively low temperatures [25,45].
The sol-gel method also allows for good control of the structural and magnetic properties of MNPs [45]. Sajjia et al. [56] prepared cobalt ferrite nanoparticles by a sol-gel method. Their results demonstrated that the saturation magnetization was 67.3 emu/g and the particle sizes were between 7 and 28 nm, according to the calcination temperature of nanoparticles.
The combustion synthesis method of MNPs is based on the thermodynamics principles and chemistry of propellants and explosives [57][58][59]. The method requires a powdered mixture, typically consisting of an oxidizing agent containing the metal ions of interest such as oxidizing reagents, and a reducing agent such as urea or glycine [57,[60][61][62][63].
Thus, the combination of total valences of reducing agent (fuel, urea) and oxidizing agent achieved gives the following expression: −40 + 6n = 0, where n is the number of moles of urea (in this case, n = 6.67 mol) for the combustion reaction. Since it is complete combustion, the stoichiometric reaction (Φe = 1) follows the definition described for the oxygen balance and equals zero.
To accomplish this, the content of oxygen from the nitrates is completely oxidized by a reducing agent (fuel) in the mixture [61].
A study conducted by Salunkhe et al. [65] evaluated the magnetic properties of cobalt ferrite nanoparticles prepared using the combustion method using glycine as fuel. The results showed that the crystallite size was 38 nm and saturation magnetization was 67.3 emu/g. Table 1 summarizes the structural and magnetic properties of CoFe 2 O 4 MNPs synthesized using various methods. Table 1. Effect of synthesis method in structural and magnetic properties of catalyst cobalt ferrite [65][66][67].

Characterization Methods
Before the synthesized magnetic materials are used as catalysts, an investigation of the various properties, which influence their performance, is essential. Some of the key parameters are size, shape, and surface area.
Therefore, this information can be elucidated using one or a combination of the following techniques: X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), BET-N 2 analysis, vibrating sample magnetometer (VSM).
X-ray diffraction (XRD) gives information about the structural properties, crystallite size, and crystalline phases of magnetic nanoparticles as catalysts.
The BET-N 2 adsorption-desorption isotherm is a technique commonly used to evaluate the porosity and specific surface area of MNPs. For example, smaller particles have a larger surface area, leading to higher photocatalytic activity due to a larger number of active sites [23]. More details are explained in Section 5.
The magnetic behavior of the ferrites (saturation magnetization) is evaluated using a vibrating sample magnetometer (VSM). The information obtained from this technique gives an idea of the recovery potential of the photocatalyst. Figure 2 shows the magnetic behavior of various ferrites at room temperature. With the exception of zinc ferrite, which has a low magnetization of saturation, the other ferrites have a high magnetization of saturation values, which implies good magnetic and recyclability properties [67].
A study conducted by Salunkhe et al. [65] evaluated the magnetic properties of cobalt ferrite nanoparticles prepared using the combustion method using glycine as fuel. The results showed that the crystallite size was 38 nm and saturation magnetization was 67.3 emu/g. Table 1 summarizes the structural and magnetic properties of CoFe2O4 MNPs synthesized using various methods.

Characterization Methods
Before the synthesized magnetic materials are used as catalysts, an investigation of the various properties, which influence their performance, is essential. Some of the key parameters are size, shape, and surface area.
Therefore, this information can be elucidated using one or a combination of the following techniques: X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), BET-N2 analysis, vibrating sample magnetometer (VSM).
X-ray diffraction (XRD) gives information about the structural properties, crystallite size, and crystalline phases of magnetic nanoparticles as catalysts.
The BET-N2 adsorption-desorption isotherm is a technique commonly used to evaluate the porosity and specific surface area of MNPs. For example, smaller particles have a larger surface area, leading to higher photocatalytic activity due to a larger number of active sites [23]. More details are explained in Section 5.
The magnetic behavior of the ferrites (saturation magnetization) is evaluated using a vibrating sample magnetometer (VSM). The information obtained from this technique gives an idea of the recovery potential of the photocatalyst. Figure 2 shows the magnetic behavior of various ferrites at room temperature. With the exception of zinc ferrite, which has a low magnetization of saturation, the other ferrites have a high magnetization of saturation values, which implies good magnetic and recyclability properties [67].
This section may be divided by subheadings. It should provide a concise and precise description of the experimental results, their interpretation, and the experimental conclusions that can be drawn. The morphology, including shape, and particle size of magnetic nanoparticles, can be determined using transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Figure 3a,b demonstrates the difference in morphology and structure of cobalt ferrite affected by different methods of synthesis [68].  [67]. Republished with permission from Elsevier.
The morphology, including shape, and particle size of magnetic nanoparticles, can be determined using transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Figure 3a,b demonstrates the difference in morphology and structure of cobalt ferrite affected by different methods of synthesis [68]. Thermal decomposition studies are crucial for the development of nanocatalysts as most of them are synthesized at high temperatures. Thermogravimetric analysis (TGA) or differential scanning calorimetry (DSC) are used to determine the optimum temperature required for the synthesis of magnetic nanoparticles due to the possibility of a loss of activity during their preparation.
Finally, these characterization techniques are also employed to investigate if any changes occur by decomposition or degradation, and whether they retain their magnetic properties after the photocatalytic process.

Photocatalytic Application of Magnetic Ferrites and Their Nanocomposites
Photocatalytic degradation is a sequence of chemical reactions promoted by light resulting in the breakdown of the target compound [69].
The photocatalytic activity is effectively dependent on the surface area and electronholes separation efficiency of the catalyst [69]. Figure 4 shows a schematic of the photocatalytic mechanism of magnetic ZnFe2O4/ZnO nanocomposite during methylene blue and methylene orange dye degradation [69]. Thermal decomposition studies are crucial for the development of nanocatalysts as most of them are synthesized at high temperatures. Thermogravimetric analysis (TGA) or differential scanning calorimetry (DSC) are used to determine the optimum temperature required for the synthesis of magnetic nanoparticles due to the possibility of a loss of activity during their preparation.
Finally, these characterization techniques are also employed to investigate if any changes occur by decomposition or degradation, and whether they retain their magnetic properties after the photocatalytic process.

Photocatalytic Application of Magnetic Ferrites and Their Nanocomposites
Photocatalytic degradation is a sequence of chemical reactions promoted by light resulting in the breakdown of the target compound [69].
The photocatalytic activity is effectively dependent on the surface area and electronholes separation efficiency of the catalyst [69]. Figure 4 shows a schematic of the photocatalytic mechanism of magnetic ZnFe 2 O 4 /ZnO nanocomposite during methylene blue and methylene orange dye degradation [69]. The morphology, including shape, and particle size of magnetic nanoparticles, can be determined using transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Figure 3a,b demonstrates the difference in morphology and structure of cobalt ferrite affected by different methods of synthesis [68]. Thermal decomposition studies are crucial for the development of nanocatalysts as most of them are synthesized at high temperatures. Thermogravimetric analysis (TGA) or differential scanning calorimetry (DSC) are used to determine the optimum temperature required for the synthesis of magnetic nanoparticles due to the possibility of a loss of activity during their preparation.
Finally, these characterization techniques are also employed to investigate if any changes occur by decomposition or degradation, and whether they retain their magnetic properties after the photocatalytic process.

Photocatalytic Application of Magnetic Ferrites and Their Nanocomposites
Photocatalytic degradation is a sequence of chemical reactions promoted by light resulting in the breakdown of the target compound [69].
The photocatalytic activity is effectively dependent on the surface area and electronholes separation efficiency of the catalyst [69]. Figure 4 shows a schematic of the photocatalytic mechanism of magnetic ZnFe2O4/ZnO nanocomposite during methylene blue and methylene orange dye degradation [69]. It has been reported that nanocatalysts that have high surface areas exhibit higher photocatalytic activity compared to their larger counterparts with lower surface area. The smaller nanoparticles support the easy transition of electrons from the valence to conduction band, thereby generating electron-hole pairs when exposed to UV-visible radiation. The generated electrons and holes further interact with dissolved oxygen and water to produce highly reactive free radical species capable of degrading the methylene dyes [69,70]. The general photocatalytic degradation mechanism of magnetic nanocomposites towards organic pollutants is demonstrated by Equations (2)- (8).
h + + H 2 O absorbed → H + + •OH (6) h + + OH absorbed − → •OH (7) •OH + MB dye → degraded products (8) Reduction and oxidation take place at the photo-excited surface of the photocatalyst. Recombination between e − and h + can occur for the use of redox reaction. The e − and h + that do not recombine are transferred to the surface of redox reaction and undergo reduction process and oxidation process to form superoxide ion (O 2 − ) and ·OH, respectively. OH − then leads to the production of strong oxidizing ·OH radicals. Meanwhile, the negative e − reacts with the oxygen (O) molecule to form a ·O 2 − . This ·O 2 − also produces ·OH radicals via the formation of HO 2 • radicals and H 2 O 2 . The radicals formed from the reaction are used to degrade the organic pollutant [71,72].

Nickel Ferrite and Nanocomposites
NiFe 2 O 4 has generated a lot of interest because of its excellent features. These include being a soft ferrimagnetic or ferrite n-type semiconductor with low coercivity, chemical stability, and electrical resistivity. These make it an excellent material in different applications such as in magnetic resonance imaging enhancement, magnetic recording media, and electronic devices, as well as in catalysis [20].
Following the description in Section 2, NiFe 2 O 4 is completely composed of an inverse spinel structure comprising a face-centered cubic lattice. NiFe 2 O 4 consists of tetrahedral sites occupied by half of the Fe 3+ cations, while the rest of the Fe 3+ and Ni 2+ cations are distributed over the octahedral sites [73][74][75]. Figure 5 shows the XRD spectra and SEM images of neat zinc oxide, nickel ferrite, and their nanocomposites [76]. In the study conducted by Adeleke et al. [76], no secondary peaks or secondary phases of material were observed; this demonstrated the effectiveness of the synthesis method used in this study.
Furthermore, SEM images demonstrated the effect of doping ferrite with zinc oxide. The high degree of agglomeration and different morphologies observed on the ZnO/Fe 2 O 4 catalyst were attributed to the magnetic attraction between nickel ferrite and zinc oxide layers [76].
Several studies have demonstrated that magnetic NiFe 2 O 4 and its nanocomposites are effective photocatalysts for the removal of dye from water and wastewater, due to their high adsorption capacity and strong photocatalytic properties [16,[77][78][79][80][81][82].
Khosravi and Eftekhar [83] synthesized magnetic NiFe 2 O 4 using a sol-gel method and evaluated its effectiveness as an adsorbent for the removal of Reactive Blue 5 (RB5) dye. Parameters such as pH, temperatures, and catalyst concentration were evaluated during RB5 degradation [83]. Maximum degradation (90%) was achieved under acidic conditions (pH = 1) at room temperature using an (adsorbent/catalyst loading of 0.03 g/L). Several studies have demonstrated that magnetic NiFe2O4 and its nanocomposites are effective photocatalysts for the removal of dye from water and wastewater, due to their high adsorption capacity and strong photocatalytic properties [16,[77][78][79][80][81][82].
Khosravi and Eftekhar [83] synthesized magnetic NiFe2O4 using a sol-gel method and evaluated its effectiveness as an adsorbent for the removal of Reactive Blue 5 (RB5) dye. Parameters such as pH, temperatures, and catalyst concentration were evaluated during RB5 degradation [83]. Maximum degradation (90%) was achieved under acidic conditions (pH = 1) at room temperature using an (adsorbent/catalyst loading of 0.03 g/L).
These findings were corroborated by Zhu et al. [16] when they evaluated the photocatalytic degradation of Congo Red dye using NiFe2O4/ZnO as a catalyst. In their study, the NiFe2O4/ZnO nanocomposite resulted in a 94% removal of Congo red solution under simulated solar light irradiation in 10 min. Nickel ferrite was also shown to be effective when coupled with other metal oxides such as TiO2.
In a study done by Hung and Thanh [84], a magnetic nanocomposite of NiFe2O4/TiO2 degraded 98% of methyl orange dye after 14 h of UV or visible light irradiation. Although the reaction time was rather long, the photocatalyst had a high saturation of magnetization (40 emu/g), which makes it easily recyclable for reuse.
The results obtained in these studies demonstrate that nickel ferrite nanocomposites are potential candidates for wastewater treatment in large-scale applications.
Additional studies that illustrate the efficacy of nickel ferrite, nickel ferrite-based titanium oxide, and zinc oxide catalysts in the degradation of variant organic pollutants are summarized in Table 2. These findings were corroborated by Zhu et al. [16] when they evaluated the photocatalytic degradation of Congo Red dye using NiFe 2 O 4 /ZnO as a catalyst. In their study, the NiFe 2 O 4 /ZnO nanocomposite resulted in a 94% removal of Congo red solution under simulated solar light irradiation in 10 min. Nickel ferrite was also shown to be effective when coupled with other metal oxides such as TiO 2 .
In a study done by Hung and Thanh [84], a magnetic nanocomposite of NiFe 2 O 4 /TiO 2 degraded 98% of methyl orange dye after 14 h of UV or visible light irradiation. Although the reaction time was rather long, the photocatalyst had a high saturation of magnetization (40 emu/g), which makes it easily recyclable for reuse.
The results obtained in these studies demonstrate that nickel ferrite nanocomposites are potential candidates for wastewater treatment in large-scale applications.
Additional studies that illustrate the efficacy of nickel ferrite, nickel ferrite-based titanium oxide, and zinc oxide catalysts in the degradation of variant organic pollutants are summarized in Table 2.

Zinc Ferrite and Nanocomposites
Zin ferrite has a small bandgap of around 1.9 eV, which gives a good response to the visible light, as well as excellent photochemical stability, considerable magnetism, and cost-effectiveness. As a result, it has also attracted attention by researchers in the photocatalysis process [85].
The compound consists of a fully normal spinel structure, where its tetrahedral sites are occupied only by Zn 2+ cations and the Fe 3+ ions are distributed in the octahedral The compound consists of a fully normal spinel structure, where its tetrahedral sites are occupied only by Zn 2+ cations and the Fe 3+ ions are distributed in the octahedral sites [86]. Figure 6 shows the XRD patterns and SEM micrographs of the zinc oxide-, zinc ferrite-, and zinc ferrite-based zinc oxide nanocomposites [17].
The photocatalyst ZnFe2O4/ZnO had diffraction peaks similar to those of neat ZnFe2O4 and ZnO. The sharp peaks showed good crystallinity of the nanocomposite [17], which demonstrates the efficacy of the synthesis method used in this study.
The SEM images revealed the effect of incorporating ZnFe2O4 nanoparticles into the pores of the ZnO matrix. The authors observed that a high content of ZnO nanoparticles was formed; these were better defined in the ZnFe2O4/ZnO nanocomposites [17]. Significant efforts have been devoted to investigating ZnFe2O4-based photocatalysts for water and wastewater treatment, with the aim of removing organic pollutants [87][88][89][90].
Yuan et al. [91] investigated the photocatalytic activity of a ZnFe2O4/TiO2 nanocomposite where the pure ZnFe2O4 and TiO2 were obtained via the co-precipitation method. The results showed that the ZnFe2O4/TiO2 and pure TiO2 resulted in 95% and 20% of degradation of phenol respectively during 180 min of irradiation under UV-Visible. This demonstrated that the ZnFe2O4/TiO2 nanocomposite catalyst was more effective than pure TiO2 in the degradation of phenol.
In addition, Shao et al. [85] evaluated the application of ZnFe2O4/ZnO nanoparticles in the photodegradation of methylene blue dye. The findings demonstrated that even after three cycles, the photocatalytic activity of the magnetic nanocomposite ZnFe2O4/ZnO (65%) was better compared to that of pure ZnO (58%), indicating the significance of ZnFe2O4 in the suppression of ZnO photo-corrosion. This was attributed to the photostability of ZnFe2O4 nanoparticles [92]. The photocatalyst ZnFe 2 O 4 /ZnO had diffraction peaks similar to those of neat ZnFe 2 O 4 and ZnO. The sharp peaks showed good crystallinity of the nanocomposite [17], which demonstrates the efficacy of the synthesis method used in this study.
The SEM images revealed the effect of incorporating ZnFe 2 O 4 nanoparticles into the pores of the ZnO matrix. The authors observed that a high content of ZnO nanoparticles was formed; these were better defined in the ZnFe 2 O 4 /ZnO nanocomposites [17].
Yuan et al. [91] investigated the photocatalytic activity of a ZnFe 2 O 4 /TiO 2 nanocomposite where the pure ZnFe 2 O 4 and TiO 2 were obtained via the co-precipitation method. The results showed that the ZnFe 2 O 4 /TiO 2 and pure TiO 2 resulted in 95% and 20% of degradation of phenol respectively during 180 min of irradiation under UV-Visible. This demonstrated that the ZnFe 2 O 4 /TiO 2 nanocomposite catalyst was more effective than pure TiO 2 in the degradation of phenol.
In addition, Shao et al. [85] evaluated the application of ZnFe 2 O 4 /ZnO nanoparticles in the photodegradation of methylene blue dye. The findings demonstrated that even after three cycles, the photocatalytic activity of the magnetic nanocomposite ZnFe 2 O 4 /ZnO (65%) was better compared to that of pure ZnO (58%), indicating the significance of ZnFe 2 O 4 in the suppression of ZnO photo-corrosion. This was attributed to the photostability of ZnFe 2 O 4 nanoparticles [92].
Further study by Patil et al. [93] investigated the photocatalytic activity of ZnFe 2 O 4 nanoparticles synthesized using a combustion method. Their activity was tested on synthetic wastewater made up of the following dyes: Methylene Blue, Rose Bengal, Evans Blue, and Indigo Carmine.
Degradation efficiencies of 98, 99, 82, and 87% were recorded for each dye, respectively [93]. The antibacterial activity of ZnFe 2 O 4 against diverse gram-negative bacterial strains such as Staphylococcus aureus, Pseudomonas aeruginosa, Escherichia coli, and Bacillus was also investigated. A variation in the antibacterial activity towards the different bacterial strains was observed [93].
Other work conducted by Sripriya et al. [94] reported on the excellent photocatalytic performance of ZnFe 2 O 4 in the degradation of 4-chlorophenol (4-CP). They further reported that factors such as particle size and surface area significantly affected the activity. Further studies on the use of magnetic ZnF 2 O 4 nanocomposites as photocatalysts are listed in Table 2.

Cobalt Ferrite and Nanocomposites
Cobalt ferrite is a hard ferrimagnetic material that has a face centered cubic structure [95]. It exists as a normal spinel structure or inverse spinel structure, depending on the synthesis method. In the normal spinel structure, the Co 2+ ions are distributed in the tetrahedral sites, while the octahedral sites are occupied by Fe 3+ ions.
For the inverse spinel structure, the tetrahedral sites are occupied by half of the Fe 3+ ions and the rest of the octahedral sites are distributed by Fe 3+ and Co 2+ ions. It is important to note that the magnetic properties vary depending on the structures [95,96]. Figure 7 shows the XRD patterns and TEM micrographs of the cobalt ferrite and cobalt ferrite-based zinc oxide nanocomposite [97]. Pristine XRD patterns were obtained with no impurities; this demonstrated that the co-precipitation method used for synthesis was highly efficient [97]. The photocatalytic activity and stability of ZnO/CoFe2O4 were confirmed by showing 10 cycles for successive reuse. Since ZnO/CoFe2O4 is recyclable and easily recovered magnetically; it is a good candidate for use as a low-cost photocatalyst for water and wastewater treatment.
Additional studies on the photocatalytic performance of cobalt ferrite and their nanocomposites in the degradation of organic pollutants are summarized in Table 2.

Manganese Ferrite and Nanocomposites
MnFe2O4 is a soft spinel ferrite with high magnetic permeability and moderate saturation magnetization, high chemical stability, high electrical resistance, and special optical properties [102]. A combination of these factors makes it attractive for use in different applications such as biomedical drug delivery and catalysis [103,104].
MnFe2O4 is considered a mixed spinel ferrite in which the tetrahedral and octahedral sites are both are occupied by Mn 2+ and Fe 3+ ions [104,105]. High reaction temperatures affect the synthesis of the magnetic ferrite, resulting in variation in particle sizes of the Several studies have demonstrated the potential of cobalt spinel ferrite doped with metals oxides (TiO 2 or ZnO) as photocatalysts for water and wastewater treatment for organic pollutants removal. This is due to the various attributes that include chemical stability, small band-gap energy that leads to activation by visible light [5,12,[98][99][100], magnetic properties, and higher surface area.
A study conducted by de Oliveira et al. [4] demonstrated that the magnetic nanocatalyst of CoFe 2 O 4 coupled to TiO 2 resulted in 100% degradation of diuron degradation. This study also observed that CoFe 2 O 4 /TiO 2 nanoparticles displayed good saturation magnetization, demonstrating that they can be easily separated for reuse.
Furthermore, Li et al. [101] reported good performance of magnetic TiO 2 /CoFe 2 O 4 nanocomposite for methylene blue (MB) degradation (98%) in 300 min. The good per-formance of magnetic TiO 2 /CoFe 2 O 4 nanocomposite was attributed to the presence of CoFe 2 O 4, which not only improved the UV light absorbance but also enhanced the response to the visible light region.
A study done by Chandel et al. [102] reported that the ZnO/CoFe 2 O 4 nanocomposite displayed 94% degradation efficiency towards Methylene Orange (MO) and 92% removal for malachite green (MG) dye. The authors attributed the hydroxyl radicals (OH • ) and holes (h + VB ) as the main reactive species responsible for the degradation of MO and MG dyes. The photocatalytic activity and stability of ZnO/CoFe 2 O 4 were confirmed by showing 10 cycles for successive reuse. Since ZnO/CoFe 2 O 4 is recyclable and easily recovered magnetically; it is a good candidate for use as a low-cost photocatalyst for water and wastewater treatment.
Additional studies on the photocatalytic performance of cobalt ferrite and their nanocomposites in the degradation of organic pollutants are summarized in Table 2.

Manganese Ferrite and Nanocomposites
MnFe 2 O 4 is a soft spinel ferrite with high magnetic permeability and moderate saturation magnetization, high chemical stability, high electrical resistance, and special optical properties [103]. A combination of these factors makes it attractive for use in different applications such as biomedical drug delivery and catalysis [103,104].
MnFe 2 O 4 is considered a mixed spinel ferrite in which the tetrahedral and octahedral sites are both are occupied by Mn 2+ and Fe 3+ ions [104,105]. High reaction temperatures affect the synthesis of the magnetic ferrite, resulting in variation in particle sizes of the material, which in turn affects other parameters such as saturation magnetization.
A study conducted by Chang et al. [106] demonstrated through X-ray diffraction analysis that no other peaks attributed a second phase were observed for manganese ferrite and titanium oxide. Additionally, peaks attributed to pure materials (MnFe 2 O 4 and TiO 2 ) were observed in the XRD pattern of MnFe 2 O 4 /TiO 2 nanocomposite (Figure 8).  The findings demonstrate that the magnetic nanoparticles were successfully synthesized via a hydrothermal followed by the sol-gel method [106]. The SEM micrograph of MnFe 2 O 4 /TiO 2 (Figure 9) showed that agglomerated spherical particles were produced.  The results showed that 90% degradation of Congo red dye was achieved in 35 min under UV-vis irradiation. Additionally, Arief et al. [103] showed that the same nanocomposite was effective for Rhodamine B dye degradation (95%). This was attributed to the presence of a narrow band gap energy (1.95 eV) of MnFe2O4/ZnO.
Silambarasu et al. [108] tested the performance of MnFe2O4 on the degradation of methylene blue dye. The manganese ferrite achieved 96% dye decolorization and exhibited saturation magnetization (Ms) of 39.7 emu/g. The magnetic properties indicated that the product could be easily recovered for potential reuse. The MnFe 2 O 4 nanoparticles display a well-defined morphology with particle size around 15-20 nm. Meanwhile, it is clearly visible that the particle size of MnFe 2 O 4 /TiO 2 is uneven and relatively large [106].
Numerous studies have demonstrated that manganese ferrite-based metal oxide nanocomposites are effective in the photocatalytic degradation of organic dyes. For example, Zamani et al. [107] evaluated the photocatalytic performance of a magnetic MnFe 2 O 4 /ZnO nanocomposite for Congo red dye (CR) removal.
The results showed that 90% degradation of Congo red dye was achieved in 35 min under UV-vis irradiation. Additionally, Arief et al. [103] showed that the same nanocomposite was effective for Rhodamine B dye degradation (95%). This was attributed to the presence of a narrow band gap energy (1.95 eV) of MnFe 2 O 4 /ZnO.
Silambarasu et al. [108] tested the performance of MnFe 2 O 4 on the degradation of methylene blue dye. The manganese ferrite achieved 96% dye decolorization and exhibited saturation magnetization (Ms) of 39.7 emu/g. The magnetic properties indicated that the product could be easily recovered for potential reuse.
There are few studies reporting the application of manganese ferrite and manganese ferrite-based zinc oxide and titanium oxide nanocomposites in water and wastewater treatment for organic pollutants removal.

Copper Ferrite and Nanocomposites
CuFe 2 O 4 is one of the magnetic nanoparticles that has become a promising candidate in the catalysis field due to the presence of surface hydroxyl groups, good chemical, and thermal stabilities, a small band gap, and magnetic properties [109]. These characteristics make it attractive as a photocatalyst for work on water and wastewater treatment for organic pollutants degradation.
Copper ferrite has an inverse spinel structure, where the tetrahedral sites are occupied by half of the Fe 3+ ions and the rest of the octahedral sites are occupied by Fe 3+ and Cu 2+ ions [110]. Therefore, besides the cubic crystal structure, the copper ferrite also presents a tetragonal crystal structure that depends on the synthesis method and annealing temperature [110].
In the XRD patterns of TiO 2 /CuFe 2 O 4 nanocomposites, the peaks associated with the neat TiO 2 and CuFe 2 O 4 were observed without any further secondary phase ( Figure 10) [109]. This demonstrated that the nanocomposite photocatalyst was successfully prepared using the Sol-Gel method and the pure titanium oxide and copper ferrite nanoparticles remained with their structure during the synthesis processes.
CuFe2O4 is one of the magnetic nanoparticles that has become a promising candidate in the catalysis field due to the presence of surface hydroxyl groups, good chemical, and thermal stabilities, a small band gap, and magnetic properties [109]. These characteristics make it attractive as a photocatalyst for work on water and wastewater treatment for organic pollutants degradation.
Copper ferrite has an inverse spinel structure, where the tetrahedral sites are occupied by half of the Fe 3+ ions and the rest of the octahedral sites are occupied by Fe 3+ and Cu 2+ ions [110]. Therefore, besides the cubic crystal structure, the copper ferrite also presents a tetragonal crystal structure that depends on the synthesis method and annealing temperature [110].
In the XRD patterns of TiO2/CuFe2O4 nanocomposites, the peaks associated with the neat TiO2 and CuFe2O4 were observed without any further secondary phase ( Figure 10) [109]. This demonstrated that the nanocomposite photocatalyst was successfully prepared using the Sol-Gel method and the pure titanium oxide and copper ferrite nanoparticles remained with their structure during the synthesis processes.  Figure 11a,b shows the SEM micrographs of CuFe2O4 and TiO2/CuFe2O4, where the presence of agglomerated particles distributed randomly is apparent. The introduction of TiO2 in the CuFe2O4 influenced the morphology of the nanocomposite TiO2/CuFe2O4. The surface of the nanocomposite was much rougher than that of the CuFe2O4.
The TiO2 agglomerated on the surface of CuFe2O4 can provide more active sites for the nanocomposite and improve its photocatalytic activity during organic pollutants degradation [109].  The TiO 2 agglomerated on the surface of CuFe 2 O 4 can provide more active sites for the nanocomposite and improve its photocatalytic activity during organic pollutants degradation [109].
Several studies have reported the photocatalytic activity of copper ferrite and its nanocomposites in water and wastewater treatment [109,111,112].
For instance, a study done by Anandan et al. [110] reported good performance of magnetic CuFe 2 O 4 as photocatalyst for the degradation of methylene blue (MB) dye in the presence of peroxydisulphate under UV-vis light.
The activity of the copper ferrite was attributed to the effect of the peroxydisulphate in the photocatalyst, which improved the photocatalytic degradation of methylene blue (95%) 75 min. Before the addition of the oxidant peroxydisulphate to the cobalt ferrite, the nanoparticles showed 16% MB dye degradation in 75 min.
A recent study conducted by Janani et al. [113] evaluated the magnetic nanocomposite ZnO/CuFe 2 O 4 as a catalyst for methylene blue dye degradation under visible light. In their study, they demonstrated that the ZnO/CuFe 2 O 4 photocatalyst was efficient in the degradation of methylene blue dye (86%) in 77 min.
The authors associated the activity of the nanocomposites with the hydroxyl radicals and holes generated, which play a principal role in the degradation of the dye. Furthermore, the photocatalyst also remained stable after six cycles of reuse. More studies on the activity of copper ferrite nanocomposites for the degradation of organic pollutants are listed in Table 2. Several studies have reported the photocatalytic activity of copper ferrite and its nanocomposites in water and wastewater treatment [109,111,112].
For instance, a study done by Anandan et al. [110] reported good performance of magnetic CuFe2O4 as photocatalyst for the degradation of methylene blue (MB) dye in the presence of peroxydisulphate under UV-vis light.
The activity of the copper ferrite was attributed to the effect of the peroxydisulphate in the photocatalyst, which improved the photocatalytic degradation of methylene blue (95%) 75 min. Before the addition of the oxidant peroxydisulphate to the cobalt ferrite, the nanoparticles showed 16% MB dye degradation in 75 min.
A recent study conducted by Janani et al. [113] evaluated the magnetic nanocomposite ZnO/CuFe2O4 as a catalyst for methylene blue dye degradation under visible light. In their study, they demonstrated that the ZnO/CuFe2O4 photocatalyst was efficient in the degradation of methylene blue dye (86%) in 77 min.
The authors associated the activity of the nanocomposites with the hydroxyl radicals and holes generated, which play a principal role in the degradation of the dye. Furthermore, the photocatalyst also remained stable after six cycles of reuse. More studies on the activity of copper ferrite nanocomposites for the degradation of organic pollutants are listed in Table 2.

Mixed-Metal Ferrites and Nanocomposites
The introduction of different cations in the spinel ferrite system is required to improve the physicochemical properties of spinel ferrites. For instance, the substitution of magnetic cations such as Mn 2+ , Ni 2+ , Co 2+ , and Cu 2+, and diamagnetic ions such as Zn 2+ and Cd 2+, in spinel ferrites systems, changes the structural, morphological, opto-magnetic, and catalytic properties [114,115]. In general, this is attributed to the distribution of metallic ions in the tetrahedral and octahedral sites [115,116].
Ciocarlan et al. [117] evaluated the structural, morphological, and photocatalytic properties of magnetic nanoparticles Co 0.5 Zn 0.25 M 0.25 Fe 2 O 4 /TiO 2, where M represent Ni 2+ , Cu 2+ , and Mn 2+ ions. XRD patterns for TiO 2 -based magnetic nanocomposites showed that the introduction of TiO 2 into the magnetic nanoparticles affected their structural properties ( Figure 12). catalytic properties [114,115]. In general, this is attributed to the distribution of metallic ions in the tetrahedral and octahedral sites [115,116].
Ciocarlan et al. [117] evaluated the structural, morphological, and photocatalytic properties of magnetic nanoparticles Co0.5Zn0.25M0.25Fe2O4/TiO2, where M represent Ni 2+ , Cu 2+ , and Mn 2+ ions. XRD patterns for TiO2-based magnetic nanocomposites showed that the introduction of TiO2 into the magnetic nanoparticles affected their structural properties ( Figure 12).  Finally, in terms of photocatalytic activity, the results demonstrated that approximately 80% and 75% of methylene orange (MO) and methylene blue (MB) were effectively degraded by Co 0.5 Zn 0.25 Ni 0.25 Fe 2 O 4 /TiO 2 . The authors attributed the good photocatalytic activity to the Ni 2+ ions and synergistic effect in combination with Co 2+ ions [117].
Several other studies have also demonstrated the photocatalytic performance of complex-structured magnetic nanocomposites. For example, a Mn 1−x Ni x Fe 2 O 4 catalyst with varying concentrations of nickel (x = 0.1, 0.2, 0.3, 0.4, and 0.5) was evaluated for indigo carmine dye degradation by Jesudoss et al. [118].
Amongst the obtained photocatalysts, the Mn 0.5 Ni 0.5 Fe 2 O 4 catalyst exhibited higher photocatalytic performance in the degradation of indigo carmine dye, with 96% degradation within a 180 min period.
The material exhibited excellent saturation magnetization of 35.0 emu/g, demonstrating that this can be recoverable after a catalytic reaction. The authors concluded that the concentration of Ni 2+ ions affected the structure of MnFe 2 O 4 , and that a high concentration of nickel ions reduced the crystallite size and increased the surface area, thereby affecting photocatalytic activity (Figure 14). Finally, in terms of photocatalytic activity, the results demonstrated that approximately 80% and 75% of methylene orange (MO) and methylene blue (MB) were effectively degraded by Co0.5Zn0.25Ni0.25Fe2O4/TiO2. The authors attributed the good photocatalytic activity to the Ni 2+ ions and synergistic effect in combination with Co 2+ ions [117]. This section may be divided by subheadings. It should provide a concise and precise description of the experimental results, their interpretation, and the experimental conclusions that can be drawn.
Several other studies have also demonstrated the photocatalytic performance of complex-structured magnetic nanocomposites. For example, a Mn1-xNixFe2O4 catalyst with varying concentrations of nickel (x = 0.1, 0.2, 0.3, 0.4, and 0.5) was evaluated for indigo carmine dye degradation by Jesudoss et al. [118].
Amongst the obtained photocatalysts, the Mn0.5Ni0.5Fe2O4 catalyst exhibited higher photocatalytic performance in the degradation of indigo carmine dye, with 96% degradation within a 180 min period.
The material exhibited excellent saturation magnetization of 35.0 emu/g, demonstrating that this can be recoverable after a catalytic reaction. The authors concluded that the concentration of Ni 2+ ions affected the structure of MnFe2O4, and that a high concentration of nickel ions reduced the crystallite size and increased the surface area, thereby affecting photocatalytic activity ( Figure 14).  A study by Naik et al. [119] evaluated the performance of nanostructured zinc-doped cobalt ferrites (Zn x Co 1−x Fe 2 O 4 with (x = 0.0 to 0.6 with the step of 0.2) in the photocatalytic degradation of Congo Red (CR) and Evans Blue (EB) dyes. They established that the photocatalytic performance of cobalt ferrite increased with an increase in Zn-doping up to x = 0.4 then decreased thereafter (Figure 15). Figure 14. Effect of Ni 2+ ions doped MnFe2O4 magnetic nanoparticles on the photocatalytic degradation (PCD) efficiency. The conditions used were IC = 150 mg/L, photocatalyst = 50 mg/100 mL, and λ = 365 nm) [118]. Republished with permission from Elsevier.
A study by Naik et al. [119] evaluated the performance of nanostructured zinc-doped cobalt ferrites (ZnxCo1−xFe2O4 with (x = 0.0 to 0.6 with the step of 0.2) in the photocatalytic degradation of Congo Red (CR) and Evans Blue (EB) dyes. They established that the photocatalytic performance of cobalt ferrite increased with an increase in Zn-doping up to x = 0.4 then decreased thereafter (Figure 15). Additional studies revealed that higher Zn 2+ doping concentrations increased the bactericidal properties of the CoFe2O4 towards human pathogens. For both Congo red (CR) and Evans Blue (EB) dyes, Zn0.4Co0.6Fe2O4 nanoparticles showed good photocatalytic activity in 150 min of irradiation time.
The study suggests that the synthesized nanoparticles are suitable for photocatalytic applications. More studies of photocatalytic activity of mixed metal ferrites nanocomposites are summarized in Table 2. The study suggests that the synthesized nanoparticles are suitable for photocatalytic applications. More studies of photocatalytic activity of mixed metal ferrites nanocomposites are summarized in Table 2.   It is important to note that, besides the focus of the development of magnetic nanocomposites for water and wastewater treatment, new recent trend of development of new materials is emerging. For example, Mir et al. [138] studied how confining AuNPs in a porous Si template can significantly enhance the photocatalytic activity of MO. The pores prevent agglomeration of nanoparticles and eliminate the need for any functionalization. Confinement of the AuNPs in the Si nanocavities prevents electron-hole recombination and facilitates the transfer of hot carriers from the Si support to accelerate the photocatalytic efficiency.
The results showed that the recyclable, low-band gap photocatalytic system has economic and environmental advantages that promote implementation of catalytic and separation processes in continuous flow mode, with the advantages associated with easier phase separation and product recovery, enhanced safety, and easier operation [138].
Another recent trend of study explored functional elastomeric copolymer membranes designed by nanoarchitectonics approach for Methylene Blue Removal. The results demonstrated specific adsorption abilities up to 18 mg/g of grafted cyclodextrins [139].
The findings obtained in these studies show that more studies can be explored in order to develop new nanomaterials that are sustainable and safer for water and wastewater applications.

Factors Affecting the Photocatalytic Activity of Magnetic Nanocomposites
The photocatalytic activity of magnetic nanocomposites is dependent on several factors such as surface area, concentrations of dopant metal ions, pH, and catalyst loading.

Catalyst Surface Area
Nanomaterials with a high specific surface area exhibit enhanced catalytic activity. A decrease in particle size takes one to the increase of the surface area, which improves the dispersion of the nanomaterials in solution. This results in an enhanced photon absorbance, leading to the retrieval of their photocatalytic performance [140][141][142][143].
A study done by Padmapriya et al. [144] evaluated the effect of surface areas of magnetic nanoparticles system Ni x Zn 1−x Fe 2 O 4 , with different concentrations of Ni 2+ ions (0.0 ≤ x ≤ 1.0) in photocatalytic degradation of methylene blue dye (Figure 16a). new materials is emerging. For example, Mir et al. [138] studied how confining AuNPs a porous Si template can significantly enhance the photocatalytic activity of MO. T pores prevent agglomeration of nanoparticles and eliminate the need for a functionalization. Confinement of the AuNPs in the Si nanocavities prevents electro hole recombination and facilitates the transfer of hot carriers from the Si support accelerate the photocatalytic efficiency.
The results showed that the recyclable, low-band gap photocatalytic system h economic and environmental advantages that promote implementation of catalytic a separation processes in continuous flow mode, with the advantages associated with eas phase separation and product recovery, enhanced safety, and easier operation [138].
Another recent trend of study explored functional elastomeric copolym membranes designed by nanoarchitectonics approach for Methylene Blue Removal. T results demonstrated specific adsorption abilities up to 18 mg/g of grafted cyclodextr [139].
The findings obtained in these studies show that more studies can be explored order to develop new nanomaterials that are sustainable and safer for water a wastewater applications.

Factors Affecting the Photocatalytic Activity of Magnetic Nanocomposites
The photocatalytic activity of magnetic nanocomposites is dependent on seve factors such as surface area, concentrations of dopant metal ions, pH, and catalyst loadin

Catalyst Surface Area
Nanomaterials with a high specific surface area exhibit enhanced catalytic activity decrease in particle size takes one to the increase of the surface area, which improves t dispersion of the nanomaterials in solution. This results in an enhanced phot absorbance, leading to the retrieval of their photocatalytic performance [140][141][142][143].
A study done by Padmapriya et al. [144] evaluated the effect of surface areas magnetic nanoparticles system NixZn1−xFe2O4, with different concentrations of Ni 2+ io (0.0 ≤ x ≤ 1.0) in photocatalytic degradation of methylene blue dye (Figure 16a). The results demonstrated that better photocatalytic activity was found for t nanocatalyst Ni0.6Zn0.4Fe2O4, which had a high surface area (36.6 m 2 /g) compared to t other samples. It can be understood from this study that surface area is also related to active sites on the catalytic surface, which enhance the photocatalytic activity.
Manikandan et al. [115] demonstrated that the photocatalytic degradation of Chlorophenol (4-CP) using the photocatalyst ZnFe2O4 was affected by the particle size a morphology of the catalyst. The results demonstrated that better photocatalytic activity was found for the nanocatalyst Ni 0.6 Zn 0.4 Fe 2 O 4, which had a high surface area (36.6 m 2 /g) compared to the other samples. It can be understood from this study that surface area is also related to the active sites on the catalytic surface, which enhance the photocatalytic activity.
Manikandan et al. [115] demonstrated that the photocatalytic degradation of 4-Chlorophenol (4-CP) using the photocatalyst ZnFe 2 O 4 was affected by the particle size and morphology of the catalyst.
Additionally, a study conducted by Jia et al. [145] reported that the photocatalytic activity of ZnFe 2 O 4 nanoparticles for methylene blue dye degradation was related to the surface properties and surface defects of the photocatalyst.

Effect of Catalyst Amount
The efficiency photocatalytic reactions can be influenced by the amount of the catalyst used. Padmapriya et al. [144] reported that the photocatalytic degradation of methylene blue dye was found to increase with an increase in the amount of the magnetic catalyst Ni 0.6 Zn 0.4 Fe 2 O 4 until a certain amount of nanocatalyst loading (Figure 16b).
However, further increase in the catalyst loading demonstrated negative influence of the degradation plateaued. The authors also reported that adding an amount of the magnetic nanocatalyst increased the active sites on the catalyst surface, which in turn increased the amount of •OH (hydroxyl) and •O 2 − (superoxide) radicals and degraded the methylene blue (MB) dye.
Furthermore, the excess of amount of nanocatalyst beyond the optimum may have resulted in the agglomeration of catalyst particles and generated turbidity, which resulted in the decrease of the photocatalytic degradation efficiency [140,142,146].

Effect of pH
Generally, the solution pH is an important variable in water and wastewater treatment as it has a significant influence on the photocatalytic degradation process of organic compounds [10]. The variation of pH alters the surface charge of heterogeneous catalysts and, consequently, changes the photocatalytic activity of catalyst [147,148]. Figure 16c shows the influence of different pH (3, 4, 5, 6, 7, 8, and 9) on the photodegradation of methylene blue using the nanomagnetic catalyst Ni 0.6 Zn 0.4 Fe 2 O 4 in a study conducted by Padmapriya et al. [144]. The results from this study showed that high photocatalytic degradation efficiency was achieved at pH = 3, due to electrostatic attraction between the anionic dye (MB) and the positively charged surface of nanocatalyst.
The authors demonstrated that at pH values above 7, the nanocatalyst surface became negatively charged, leading to electrostatic repulsion between the methylene blue dye and the catalyst, which reduced the photocatalytic degradation efficiency. More studies demonstrating the same behavior were reported by Mirkhani et al. [149] and Suwarnkar et al. [150].

Reusability of the Magnetic Nanocatalyst
Heterogeneous photocatalysis technology is always looking for an ideal photocatalyst, one that is reusable and that possesses high photocatalytic efficiency, a large specific surface area, and ability to absorb visible light [138]. Thus, the recyclability of catalysts is one of the key steps towards the sustainable application of photocatalysts and development of heterogeneous photocatalysis technology for water and wastewater treatment. The recyclability of catalysts is also related to their actual operational costs.
Krishna et al. [100] reported the reusability of the CoFe 2 O 4 /TiO 2 nanocatalysts for acid blue 113 (AB113) dye degradation through magnetic separation where its photocatalytic activity was found to be retained up to six consecutive cycles and without considerable loss of photocatalytic activity and stability ( Figure 17). Table 3 shows additional results of the activities of reused magnetic nanocomposites for organic photodegradation processes. Most of the magnetic nanocomposites are recyclable up to more than three runs, demonstrating their stability during their application for water and wastewater treatment for organic pollutants removal. Therefore, these studies are indicators for possible industrial or large-scale application.  [100]; and (c) magnetic responsiveness of CoFe2O4/TiO2 with an external magnetic field [153]. Republished with permission from Elsevier.

The Overlooked Social Dimension
The focus of most water and wastewater-related research has been on the technical aspects of the problem and improvements in terms of water quality and in minimizing environmental and health impacts, with very limited attention to its basic social and cultural sustainability dimensions [158].
A study done by Wichelns et al. [159] demonstrated that there is a need for a paradigm shift from the 'treatment for disposal' to the 'treatment for reuse' since wastewater contains pollutants such as organic and inorganic compounds which may pose health risks if not well managed [159].
Additionally, even when wastewater is treated using advanced technologies and health risks are carefully addressed and controlled, irrespective of all scientific evidence, the social perception remains the driver of the success or failure of wastewater reuse schemes [158].
Depending on public perceptions, impressions, and attitudes, the development of a wastewater scheme can be supported or constrained. Negative public perception can prevent well-planned projects from moving forward. On the other hand, positive public perception, which leads to greater acceptance, is the key element for the successful implementation of wastewater treatment [159,160].
Saad et al. [158] reported that various local communities around the world have rejected several water and wastewater treatment projects by their governments due to inadequate community consultation which resulted in negative public perception.
In summary, it can be said that recognizing the role of the social base for wastewater management from risk reduction to reuse can have major implications, for example, on the choice and effectiveness of the technologies employed.  [100]; and (c) magnetic responsiveness of CoFe 2 O 4 /TiO 2 with an external magnetic field [153]. Republished with permission from Elsevier.

The Overlooked Social Dimension
The focus of most water and wastewater-related research has been on the technical aspects of the problem and improvements in terms of water quality and in minimizing environmental and health impacts, with very limited attention to its basic social and cultural sustainability dimensions [158].
A study done by Wichelns et al. [159] demonstrated that there is a need for a paradigm shift from the 'treatment for disposal' to the 'treatment for reuse' since wastewater contains pollutants such as organic and inorganic compounds which may pose health risks if not well managed [159].
Additionally, even when wastewater is treated using advanced technologies and health risks are carefully addressed and controlled, irrespective of all scientific evidence, the social perception remains the driver of the success or failure of wastewater reuse schemes [158].
Depending on public perceptions, impressions, and attitudes, the development of a wastewater scheme can be supported or constrained. Negative public perception can prevent well-planned projects from moving forward. On the other hand, positive public perception, which leads to greater acceptance, is the key element for the successful implementation of wastewater treatment [159,160].
Saad et al. [158] reported that various local communities around the world have rejected several water and wastewater treatment projects by their governments due to inadequate community consultation which resulted in negative public perception.
In summary, it can be said that recognizing the role of the social base for wastewater management from risk reduction to reuse can have major implications, for example, on the choice and effectiveness of the technologies employed.
Added to this is the creation of economic incentives for the public and private sector institutions to invest in sanitation and to generate income for private operators as well as secure their sustainability [161].

Conclusions and Recommendation
The development and application of magnetic ferrite-based titanium oxide and zinc oxide nanocomposite as catalysts are extremely promising for the removal of organic pollutants from water and wastewater, as shown by various studies presented in this review. Studies demonstrated that these catalysts can be prepared by different methods such as sol-gel, co-precipitation, hydrothermal, and combustion. However, the methods of synthesis are chosen based on their advantages. The magnetic nanoparticles (MNPs) have several advantages, including that they are easily separated by an external magnetic field without loss of the nanocatalyst, which can be reused up to several runs of experiments. In most of studies, the magnetic based titanium oxide and zinc oxide nanocomposite exhibited an excellent catalytic activity for organic pollutants removal. Additionally, some studies showed that these catalysts were even effective after more three successive cycling runs. The catalytic activity of the MNPs as catalysts is a direct outcome of its intrinsic characteristics as well as of its synthesis method; nevertheless, the catalytic performance can be influenced by conditions that are imposed on these materials to prepare them for a given application. Additionally, the method of synthesis plays a principal role in the physicochemical properties of the catalyst obtained. However, the synthesis of magnetic nanoparticles and their relevance for organic dyes removal from water and wastewater still require more investigation in order to achieve the optimum optimization for large-scale for subsequent practical applications. Finally, studies of the application of MNPs-based oxides nanocomposites in water and wastewater treatment are still few; however, more studies are still required. Additionally, with this technology in progress, scientists have enough supporting theory to upscale and provide a cleaner environment and safe drinking water to human populations.

Conflicts of Interest:
The authors declare no conflict of interest.