1. Introduction

Heterogeneous photocatalysis is a sustainable and green technology used for contaminated water treatment and recycling [1]. It is considered a suitable technique because of its cost-effectiveness, eco-friendliness, high efficiency, and broad applicability and offers great potential for the overall mineralization of hazardous materials from the environment. Almost complete degradation and mineralization of organic pollutants such as pesticides, herbicides, phenols, antibiotics, hydrocarbons, plastics, etc., are achieved even under mild cases of temperature and pressure [2,3,4,5]

Numerous semiconductor materials, such as titanium dioxide (TiO₂), zinc oxide (ZnO), and silica (SiO₂) [6], Cu/Cu@UiO-66 [7], are presented as promising photocatalysts. There are several investigators who worked on TiO₂ and ZnO as photocatalysts owing to their unique and extraordinary photocatalytic properties, such as a non-toxic nature, economically viability, chemical stability, high reactivity, etc., but ZnO has the ability to show photocatalytic efficiency in both the ultraviolet (UV) and visible light. Youji Li et al., improved the photocatalytic efficiency of TiO₂ in visible light by doping N and successfully degraded acid orange 7 dye through visible-light-responsive N-doped mesoporous titania on carbon fibers in 2015 [8]. In the year 2017, Lin Xiao et. al. fabricated a visible-light-driven photocatalyst composed of mesoporous TiO₂ (MT) doped with Ag⁺-coated graphene (MT-Ag/GR) and degraded methylene blue dye [9]. Yufen Gu et al., in 2022, synthesized ZnSn(OH)₆ (ZSO) by hydrothermal method and degraded methylene blue and Hexadecyl trimethyl ammonium Bromide-ZSO (CTAB-ZSO) [10]. Recently, Liexiao Li et al., fabricated a flower-like Bi₂O₂CO₃ photocatalyst and studied its photocatalytic efficiency by the reduction in Cr (VI) in the year 2022 [11].

There is always a need to synthesize a new photocatalyst to fulfil this purpose and try to improve the catalytic efficiency of ZnO by tailoring its particle size, amount of oxygen defects, facets, and surface area modification [12].

In the present scenario, nanosized materials have gained much more focus due to their novel physical properties (such as structural, electronic, and thermal), which are of high scientific interest in basic and applied scientific fields, such as catalysts, sensors, photoelectron devices, and highly effective and working devices [13,14]. In this paper, we synthesized nanostructured ZnO, which has a great advantage in photocatalytic reactions due to its large surface-to-volume ratio and catalytic efficiency [15,16,17,18]. The catalytic potential of ZnO NPs was tested by the kinetic study of malachite green (MG) dye under eco-friendly LEDs irradiation. LEDs (p-n junction semiconductor devices) irradiations were chosen as the source of light since they have high and stable energy efficiency, are economically viable, provide continuous exposure of light as compared to traditional energy sources, and are eco-friendly, since conventional light sources are made up of mercury filament, which is hazardous for the environment [19,20,21].

Recently, ZnONPs were successfully synthesized from the Manilkara zapota, Lipia adoensis, and Passiflora caerulea. In this study, the investigators used the sapota plant since the plant contains different reducing phytoconstituents, such as alkaloids, phenolic compounds, sterols, amino acids, terpenoids, vitamins, etc., which can reduce metallic ions into metal nanoparticles [22,23,24,25].

Sapota plant leaf extract was used to synthesize ZnO NPs. The sapota plant belongs to the Sapotaceae family, of the Pouteria sapota (Latin name) species, and the botanical name is Manilkara zapota. The sapota plant is cultivated between 15 °C and 38 °C temperatures in moist tropic or subtropical areas [26].

In this mechanism, the electron of the valence band gets promoted into the conduction band on the irradiation of the light on the nanoparticles in the aqueous medium. The OH⁻ ions lose their electrons on the valence band and form hydroxyl radicals, which are responsible to oxidize dye molecules. Simultaneously, oxygen reduced by the electrons of the conduction band form O₂^. radicals (Figure 1) [27].

Various reaction parameters, such as the effect of change in Fenton’s reagent concentration, CO_2, and COD measurements, and the effect of the bubbling of N₂ and O₂ purging, were evaluated during MG dye degradation. All the observed results are correlated and the improved catalytic efficiency is interpreted based on the structural and morphological findings of the prepared nanosized ZnO.

In the present study, authors first synthesized Pouteria-sapota-mediated zinc oxide nanoparticles. Further, the confirmation of the formation of the particle and its purity was analyzed using sophisticated instruments such as FESEM, XRD, and FTIR. The potential of the synthesized ZnO NPs was assessed for the remediation of MG dye under light-emitting diode conditions. The object was to develop a green route for the synthesis of zinc oxide nanoparticles and their potential to eliminate the MG dye from the aqueous solution efficiently.

2. Experimental Analysis

2.1. Sapota Plant Leaf Extraction

About 100 g of sapota plant (Manilkara zapota) leaves was obtained from the university campus of the Lakshmangarh (India) area in the summer season and washed with double-distilled water to remove the dust and dirt present on the leaves. Leaves were air-dried and ground into fine powder in the cleaned mortar with 400 mL of double-distilled water. The liquid was transferred into a 500 mL beaker and concentrated by heating on a hot plate at 60 °C temperature for 1 h with continuous stirring. The suspension was cooled, filtered, and used for the preparation of ZnO NPs [28].

2.2. Synthesis of Nanostructured ZnO

ZnO NPs was prepared by using the leaf extract of the sapota plant. Here, about 100 mL of aqueous solution zinc nitrate (0.45 mol L ^–1) was prepared in double-distilled water. After that, 30 mL of leaf extract and 50 mL of zinc nitrate solution were mixed drop by drop along with continuous stirring. Then, the beaker was covered by the aluminium sheet for 2 h at 30 °C. The developed particles were carefully washed with double-distilled water and kept in an oven at 60 °C. Finally, the ZnO NPs were calcinated in a muffle furnace at 300 °C for 6 h [29].

2.3. Experimental Procedure

The photocatalytic mineralization of the MG dye solution was conducted in a specially designed double-walled special glass vessel, which maintained constant temperature during the experiment. During a typical photocatalytic experiment, 100 mL of MG dye solution and nanosized ZnO were taken in a slurry-type batch reactor. After stirring for 10 min, the mixture was placed in the dark for 30 min to attain absorption–desorption equilibrium. A slurry containing aqueous dye solution and ZnONPs was then irradiated under the LEDs (250W). After 3 min of time interval, the absorbance of the solution was taken after centrifugation by spectrophotometer. Variation in absorption spectra was measured at 400–620 nm λ_max on a spectrophotometer (Systronic Model No.166). A Lux-meter (Lutron LX-101) was used to measure the intensity of visible light. The mineralization efficiency of the process was calculated as:

$\% \mathrm{efficiency}=\frac{{\mathrm{C}}_0 -\mathrm{C}}{{\mathrm{C}}_0}\times 100$

2.4. Characterization of the ZnO Nanoparticle

The X-ray pattern of the prepared ZnO NPs was recorded on the PANalytical Empyrean diffractometer and studied in the range of 20–80° (2θ). The average crystallite size of the nanosized ZnO was determined with the help of the Scherrer formula.

$\mathrm{D}=\mathrm{K}\frac{\lambda }{\beta \mathit{cos}\theta }$

The surface morphology and mean particle size of the sample were analyzed by a field scanning electron microscope (FESEM). The presence of functional groups in the sample was identified by Fourier transform infrared spectroscopy (FTIR) by using Bruker model ALPHA FTIR.

3. Results and Discussions

3.1. Structural Studies of ZnO Nanoparticle

The intense and narrow peaks from the XRD suggest that the product has good crystalline morphology (Figure 2). The diffraction of the peaks around 31.46°, 34.41°, 36.57°, 47.66°, 56.72°, 62.70°, and 67.95° were indexed to (100), (002), (101), (102), (110), (103), and (112) planes, respectively, which confirmed the synthesis of ZnO NPs as wurtzite-type (hexagonal structure). The d-values and lattice parameters of ZnO NPs were determined [a = b = 3.256 A° and C = 5.220 A° (calculated values) and a = b = 3.250 A° and 5.207 A°] according to JCPDS 36-1451, which are favored to the JCPDS data file for ZnO powder. The calculated average crystallite size of ZnO nanoparticles was observed at 36.73 nm with the help of the Debye–Scherrer formula [30,31,32]. Similar results were also obtained by Hawwary et al., 2021 and Degefa et al., 2021, where the peaks were also obtained at 31.77, 34.43, 36.36, 47.55, 56.60, and 62.87 [33,34,35]. The major peak was at 36.6°. The above result shows the crystalline form of the wurtzite type.

The FESEM images (Figure 3) show the general surface morphology of nanosized ZnO. It indicated that the particles are cylindrical in shape and have an average particle size in the range of 20–30 diameter and 150 nm length. Degefa et 2021 also obtained similar type of ZnO NPs by using extracts of onion [34]. Modi et al., 2022 also reported the synthesis of ZnO NPs by using onion peel extracts with similar morphology [32]. Spoiala et al., 2021 also obtained ZnO NPs of similar morphology [36].

Figure 4 shows a typical FTIR spectrum of ZnO NPs. The characteristic band at 531 cm⁻¹ and 589 cm⁻¹ is assigned to the stretching vibrations of the Zn-O bond. This confirms the formation of ZnO NPs. A few investigators have also obtained bands in the region of 400–500 cm⁻¹, but here we performed analysis from 500 onwards. Spoiala et al., 2021, also obtained bands in the region of 419 to 469 cm⁻¹, which were assigned to the Zn-O bond [36].

A small band at 1510 cm⁻¹ could be due to the precursor material used for the synthesis of ZnO NPs, i.e., zinc nitrate. So, the COOH group and OH are present in the region of 1500 to 1650 cm⁻¹. This precursor might have failed to take part in the reaction and could not transform into ZnO NPs [37,38]. The formation of the ZnO wurtzite structure (Figure 4) in the sample was also supported by the XRD and FESEM [39,40].

3.2. Photocatalytic Experiments

In this study, the photocatalytic efficiency of the nanosized ZnO NPs was observed by the degradation of MG dye. The degradation rate was very low when only visible light was given to the dye solution. In the absence of ZnO NPs and without LEDs irradiation, no degradation was observed. Both LEDs light and ZnO NPs were essential for the mineralization of the MG dye solution. For the confirmation of the photocatalytic mineralization process, we studied different parameters by optimization of the reaction conditions.

3.2.1. Effect of Change in Fenton’s Reagent Concentration

A mixture of ferrous ions and H₂O₂ known as Fenton’s reagent was used as a powerful oxidant for organic pollutants. Among advanced oxidation processes, catalytic oxidation using Fenton’s reagent and similar reagents is a prominent procedure for effective dye degradation due to its low cost and lack of toxicity. The efficiency of Fe³⁺/H₂O₂ has been investigated for the mineralization of MG dye by ZnO NPs and visible light. Firstly, we tested the photodegradation of MG dye under different molar ratios. Upon irradiation of the Fe³⁺/H₂O₂/ZnO/MG method in the presence of LEDs irradiations, we found improved degradation of the MG dye, as compared to the dye solution without ZnO NPs (Figure 5) [41,42,43].

3.2.2. Measurement of Chemical Oxygen Demand (COD) and CO₂

The COD test has commonly been used to measure the presence of organic waste and permits the measurement of O₂ necessary for the mineralization of the organic dye into CO₂ and H₂O_. The COD of the MG-containing solution was determined by pre- and post-treatment of the MG dye solution. The mineralization and decolorization of dye are indicated by a considerable reduction in COD value. The decrease in the COD (chemical oxygen demand) values from 270 mg/L and enhancement in CO₂ values in 115 min in the presence of LEDs irradiation confirmed the complete oxidation as well as mineralization of the treated dye solution [44,45]. The results are shown in Figure 6a,b.

3.2.3. Effect of Bubbling of N₂ and O₂ Purging

For this test, pure nitrogen and oxygen were purged into the photo-reactor in order to study their effect on the photocatalytic mineralization of MG dye. Oxygen is another important oxidizing agent and not only helps in the degradation of dye but reduces electron-hole recombination as well [46]. The graph showed that the degradation of MG was tremendously retarded by the bubbling of pure N₂ but increased rapidly on bubbling O₂ through the dye solution. The results are shown in Figure 7.

3.2.4. Effect of Other Photocatalysts

Different photocatalysts were tested, and it was found that ZnO NPs are more suitable to degrade MG dye, as compared to other photocatalysts. The rate constant values for the ZnO NPs were 3.4 × 10⁻⁴ s⁻¹. The order of efficiency of the tested photocatalysts is: ZnO > TiO₂ > BiOCl > BaCrO₄ > CdS, as shown in Table 1.

3.2.5. Mechanism of Malachite Green Dye Degradation

Previous studies based on the degradation of organic pollutants revealed that hydroxyl radical (OH) is an important oxidizing agent and plays a crucial role in the mineralization of organic pollutants in the aqueous medium. The electron-hole pairs are produced when aqueous ZnO suspension is irradiated. The generated electron-hole pairs can interact with the dye separately. These VB holes oxidize OH⁻ or H₂O into active ^•OH radicals, while CB electrons form superoxide radicals (O₂^•−) by a reduction in O₂ [47,48]. The overall mechanism can be summarized as:

(1)$\mathrm{ZnO}+{ \mathrm{h}\mathsf{\nu }}_{\mathrm{visible}} \stackrel{}{\to } \mathrm{nanosized} \mathrm{ZnO} \left({\mathrm{h}}_{ \mathrm{VB}}^{+}+\mathrm{VB}+{\mathrm{e}}_{ \mathrm{CB}}^{-}\right)$

(2)$\mathrm{ZnO} \left({\mathrm{h}}_{ \mathrm{VB}}^{+} \right)+{\mathrm{H}}_2\mathrm{O} \stackrel{}{\to } \mathrm{ZnO} +{\mathrm{H}}^{+}+{ \mathrm{OH}}^{•}$

(3)$\mathrm{ZnO} \left({\mathrm{h}}_{ \mathrm{VB}}^{+} \right)+{\mathrm{OH}}^{-} \stackrel{}{\to } \mathrm{ZnO} +{\mathrm{OH}}^{•}$

(4)$\mathrm{ZnO} \left({\mathrm{e}}_{ \mathrm{CB}}^{-}\right)+{ \mathrm{O}}_2 \stackrel{}{\to } \mathrm{ZnO} +{\mathrm{O}}_2^{•-}$

(5)${\mathrm{O}}_2^{•-}+{ \mathrm{H}}^{+} \stackrel{}{\to }{ \mathrm{H}}_2{\mathrm{O}}^{•}$

(6)${\mathrm{H}}_2{\mathrm{O}}^{•}+{\mathrm{H}}^{+}+ \mathrm{ZnO} \left({\mathrm{e}}_{ \mathrm{CB}}^{-}\right) \stackrel{}{\to }{ \mathrm{H}}_2{\mathrm{O}}_2+ \mathrm{ZnO}$

(7)${\mathrm{H}}_2{\mathrm{O}}_2+ \mathrm{ZnO} \left({\mathrm{e}}_{ \mathrm{CB}}^{-}\right) \stackrel{}{\to }{ \mathrm{OH}}^{•}+{ \mathrm{OH}}^{-}+\mathrm{ZnO}$

(8)$\mathrm{MG}+{ \mathrm{OH}}^{•} \stackrel{}{\to }{ \mathrm{CO}}_2^{}+{ \mathrm{H}}_2{\mathrm{O}}_2+{\mathrm{NO}}_3^{-}$

The resulting ^•OH produced is a very strong oxidizing agent and can oxidize MG dye into CO₂, H₂O, and mineral acids in LEDs irradiation.

4. Conclusions

This investigation reports the preparation of nanostructured ZnO by a green, cost-effective technique, used effectively in the mineralization of malachite green dye by using LEDs irradiation as a source of visible light. As prepared, ZnO NPs showed better photocatalytic activities for the mineralization of malachite green dye compared to other photocatalysts (TiO₂, BiOCl, BaCrO₄, CdS), due to the suitable surface morphology and high efficiency. A significant enhancement of photocatalytic degradation was observed in the system using a combination of Fenton’s reagent (Fe³⁺ + H₂O₂) and photocatalyst in the presence of visible light. A remarkable decrease in COD and increase in CO₂ was noticed during the reaction, whereas a tremendous decrease in degradation occurred when pure N₂ purged and increased rapidly on the bubbling of O₂ through the dye suspension. Characterization studies confirmed the external morphology, average particle size, and wurtzite structure of ZnO NPs. This nanostructured-ZnO-assisted photocatalysis promises to be a versatile, inexpensive, eco-friendly, and efficient method for the treatment of textile effluents in general.

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Figure 1. Physical mechanism of degradation of dye by NPs.

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Figure 2. XRD pattern of ZnO NPs.

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Figure 3. FESEM micrographs of ZnO NPs (a–d).

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Figure 4. FTIR spectrum of ZnO NPs.

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Figure 5. Effect of change in Fenton’s reagent concentration.

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Figure 6. (a) measurement of COD removal (b) Measurement of CO2 and nitrate removal.

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Figure 7. Effect of bubbling of N2 and O2 purging.

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