Introduction

In science and technology, nanotechnology has emerged as a rapidly emerging concept in recent years and has undergone remarkable development. It is a branch of science and engineering that deals with materials having dimensions in the range of 100 nm or less1,2. Due to their large surface area-to-volume ratio, nanomaterials are nanoscale in size and are very small particles with improved thermal conductivity, catalytic reactivity, nonlinear optical performance, and chemical stability3.

In recent years, many chemical and physical methods have been developed for the synthesis of metallic nanoparticles; these methods serve as important methods in the development of nontoxic, clean, and eco-friendly procedures4 and can control, appreciate, and manipulate matter at the level of individual atoms and molecules5. The small dimensions of nanoparticles provide extraordinary surface-to-volume ratios, which permit the confinement of electron motion inside boundaries, which is associated with improving their optical properties. This makes them particularly desirable in various application areas, such as medicine6, drug delivery7, water purification8, agriculture9, food10, solar cells11, cosmetics12, and textiles13.

Metals and metal oxide nanomaterials exhibit vital physicochemical properties, which include increased conductivity, catalytic activity, unusual optical properties, and pyromechanical properties. They also have antimicrobial activity against pathogenic microorganisms10,11,12,13. Nanotechnology is a powerful tool for preventing environmental pollution from different industrial wastes. Due to the increasing use of organic compounds in various industrial and agricultural sectors, environmental safety has become a serious problem for society14.

Organic pollutants have considerable adverse effects on aqueous environments. Among the different organic pollutants, dyes are the most frequently used pollutants and are discharged into aqueous environments15. Dyes are hazardous, carcinogenic, toxic, and adversely affect human health, the environment, and aquatic ecosystems. They are classified by their structural basis as basic dyes, acidic dyes, azo dyes, disperse dyes, anthraquinone-based dyes, and metal complex dyes16,17,18.

The paint and varnishes, textiles, plastics, ink, cosmetics, and pharmaceutical industries use a large number of organic dyes and their intermediates. Some of these color dyes are extremely toxic and pose a major hazard to the surrounding ecosystem16,19. The dye manufacturing industry represents a relatively small part of the overall chemical industry. The worldwide production of dyes is nearly 800,000 tons per year. Approximately 15% of synthetic dyes are lost during different processes in the textile industry20. Synthetic dyes are valuable in numerous industries, such as textiles, paper printing, food, pharmaceuticals, leather, and cosmetics. There are more than 10,000 dyes used in textile manufacturing alone, nearly 70% of which are azo dyes; these dyes are complex in structure and are synthetic in nature21.

Aromatic amines such as crystal violet (CV) and methylene blue (MB) can be mobilized by water or sweat, which encourages their absorption through the skin and other exposed areas, such as the mouth22. They are used in the textile and paper dye industries, as well as in navy blue and black ink for printing, ballpoint pens, and inkjet printers. It is also used to colorize diverse products, such as fertilizers, antifreeze agents, detergents, and leather24. CV and MB have been classified as recalcitrant dyes extensively used in textile processing and as biological stains in veterinary and human medicine. The toxicity of these dyes to human beings and terrestrial and aquatic life causes harmful effects such as cyanosis, vomiting, an increase in heartbeat, quadriplegia, shock, jaundice, and tissue necrosis, prevents the penetration of sunlight into water, reduces photosynthetic function in plants, and harms both aquatic ecosystems and marine vegetation23,24,25.

Synthetic organic dyes and pigments discharged from various industries are responsible for causing substantial environmental pollution26,27, as they cannot be degraded by conventional water treatment processes due to their complex aromatic structures, hydrophilic nature, and high stability against light, temperature, water, and chemicals16,28. In this view, the degradation of organic dye molecules in waste has gained paramount attention19. To date, for the treatment of industrial effluents, various physical and chemical processes, such as ion exchange, adsorption, flocculation, UV radiation, electrochemical reduction, and ionization, have been developed for the elimination of dyes21,29,30,31.

However, most of these processes are associated with secondary pollution problems23, complicated procedures, high costs, a pricey setup, relentless energy input32, low dye removal efficiency, and the discharge of massive amounts of sludge and toxic intermediates to the environment; additionally, these processes lack practical utility26,27. Although photocatalytic oxidative degradation of organic dyes and pollutants is effective, these processes are also slow and inherently energy-consuming. Hence, the development of an effective and eco-friendly protocol for the treatment of industrial effluents is needed. Therefore, designing and synthesizing a catalytic material possessing suitable redox potential between the electron donor and acceptor species to act as an efficient electron relay system is challenging. Interestingly, metal nanoparticles are viable enough to reduce the potential difference because of their high Fermi potentials, which can result in excellent dye degradation efficiency33,34. The catalytic reductive degradation of organic dye molecules by metal nanoparticles in the presence of NaBH4 occurs by an electron transfer process. Metal nanoparticles could make the process kinetically feasible by lowering the activation energy33,35.

In these processes, there may be a large redox potential difference between the electron donor (BH4 ion) and acceptor (dye) species, which can hamper the relay of electrons27. In contrast, catalytic reductive degradation of organic dye molecules by metal nanoparticles in the presence of NaBH4 is a relatively fast process and was recently used extensively because of its several advantages over other technologies36,37. This advantage includes the complete degradation of pollutants, simple and easy treatment procedures, and no secondary pollutant generation38. For the catalytic degradation of these organic dyes, different nanomaterials, including metal and metal oxide nanoparticles, need to be prepared. Various methods, such as physical, chemical, and biological methods, are used for the synthesis of nanoparticles. The biological method (green method) is the preferred technique because it is more cost-effective, eco-friendly, and easy to use than the other methods39. Moreover, plant extracts naturally act as reducing, stabilizing, and capping agents for the synthesis of NPs. Iron nanoparticles (FeNPs) are considered efficient catalysts for dye degradation in the presence of BH4- as an ion donor due to their large surface area, high reactivity, and outstanding photochemical stability33. The specific surface area of FeNPs is 33.5 m2 g−1, while that of granular iron is only 0.9 m2 g−1, which is much less than that of nanosized iron40.

Vernonia amygdalina is a tree that belongs to the Asteraceae family and is a very common plant that grows predominantly in the eastern and western parts of tropical Africa. In addition, it is popularly called bitter leaf in English. Vernonia amygdalina grows in most parts of Ethiopia and is known as the ‘grawa’ in Amharic16. The leaves of Vernonia amygdalina have been found to be relevant in traditional folk medicine as an anthelming agent, a laxative herb, and an antimalarial agent39, as they are known as quinine substitutes40,41.

Vernonia amygdalina is a plant that has been traditionally used for its antibacterial properties and for maintaining the health of organs such as the kidney and liver, thanks to its therapeutic elements such as saponins, venomygdin, and vernodalin38. Leaf decoctions are used to treat fever, malaria, diarrhea, dysentery, hepatitis, and cough; as laxatives; and as fertility inducers16. They are also used as medicines for scabies, headaches, and stomachaches. Root extracts are also used as treatments for malaria and gastrointestinal disorders41. However, despite its excellent medicinal properties, its pharmacological and environmental actions have not been fully explored. Our research aimed to address this gap by using Vernonia amygdalina extracts as stabilizers to control the size of FeNPs during synthesis. We hope that this will promote the use of Vernonia amygdalina in environmental applications. Our study describes the environmentally friendly biosynthesis and characterization of iron nanoparticles using Vernonia amygdalina extracts as reducing and capping agents. Additionally, we report the characterization and application of these nanoparticles in the catalytic degradation of crystal violet and methylene blue.

Results and discussion

Visual inspection for the synthesis of iron nanoparticles

NPs exhibit a different array of colors during synthesis. Plant extracts contain several phytochemicals that react with metal ions and convert them to nanoparticles42. During the synthesis of the iron nanoparticles, a change in color from light brown to grayish black was observed within 5 min after the addition of the Vernonia amygdalina leaf extract, indicating the formation of iron nanoparticles (Fig. 1). After 24 h of reaction, the color change stopped, and precipitation was observed, confirming that the nanoparticle synthesis process was complete43.

Figure 1
figure 1

Visual observation of the green synthesis of FeNPs.

Characterization of synthesized nanoparticles

Ultraviolet‒visible spectroscopy analysis of FeNPs

The successful formation of the biosynthesized FeNPs was confirmed by measuring their absorbance at wavelengths ranging from 200 TO 800 nm via UV‒vis spectroscopy. This technique is a powerful tool for detecting the formation of nanoparticles on the surface plasmon resonance (SPR) peak and for calculating their band gap energy. The continuous absorption of the UV‒Vis spectrum in the SPR region confirmed the formation of greenly synthesized FeNPs, which were observed to be nanoscale particles (as depicted in Fig. 2). This observation suggested that the biosynthesized FeNPs may be amorphous and polydispersed. Additionally, the absorbance spectrum of FeNPs obtained using aqueous Vernonia amygdalina leaf extract was similar to that of previous reports on FeNPs synthesized using aqueous tea and sorghum extracts44, Catharanthus roseus leaf extracts45, and Calotropis gigantea flower extract46.

Figure 2
figure 2

UV‒Vis spectrum of the synthesized FeNPs.

Fourier transform infrared (FT-IR) spectral analysis of the FeNPs

Fourier transform infrared (FT-IR) spectroscopy was employed in this study to determine the surface composition of the synthesized FeNPs, mainly the specific functional groups that may contribute to the formation of FeNPs. Thus, this technique provides information on the interactions between phytochemicals present in plant extracts and the metal ions responsible for the production and capping of iron nanoparticles. This was confirmed in terms of the individual band intensities observed in the extracts and their corresponding nanoparticles. The FT-IR spectra of the Vernonia amygdalina leaf extract and the synthesized FeNPs are shown in Fig. 3. The FT-IR spectrum of the leaf extract showed intense bands at 3360.35 cm−1 (O–H stretching vibrations), 2913.26 cm−1 (C–H and CH2 vibrations of aliphatic hydrocarbons), 2829.26 cm−1 (C–H stretching of aldehydes), 1646.95 cm−1 (C = C stretching vibrations), 1373.11 cm−1 (C–O stretching of the ester group), and 1039.88 cm−1 (due to C–O bonds). The FT-IR spectrum of FeNPs displays intense bands at 3391.35 cm−1 (O–H stretching vibrations), 2921.06 cm−1 (C–H and CH2 vibrations of aliphatic hydrocarbons), 1631.74 cm−1 (C = C stretching vibrations), 1259.83 cm−1 (C–O stretching of the ester group) and 1078.27 cm−1 (due to C–O bond stretching of the primary alcohol), as well as absorption bands at approximately 554 cm−1, which corresponds to the Fe–O bond. A comparison of the FT-IR spectra of Vernonia amygdalina and the Fe NPs revealed a band shift toward higher frequencies from 3360.96 to 3391.06 cm−1 (O–H stretching vibrations), 2913.26 to 2921.06 cm−1 (C–H and CH2 vibration of aliphatic hydrocarbons) and 2829.88 to 2837.87 cm−1 (C–H starch of aldehyde), suggesting the possible association of the polyphenol compounds in the leaf extract with metal ions in the formation of FeNPs. The absorption peak of the nanoparticles was similar to that of the extracts, and the differences in intensities suggested the importance of functional groups in the reduction and capping processes. The soluble elements present in the Vernonia amygdalina leaf extract could have acted as capping agents preventing the aggregation of FeNPs47.

Figure 3
figure 3

FTIR spectra of the green-synthesized FeNPs (blue spectrum) and the Vernonia amygdalina leaf extract (green spectrum).

X-ray diffraction (XRD) analysis of the FeNPs

X-ray diffraction (XRD) analysis was employed to explore the surface crystallinity of the biosynthesized iron nanoparticles, revealing predominantly amorphous FeNPs supported by indistinct diffraction peaks (Fig. 4). Similarly, prior investigations have reported the production of amorphous FeNPs using leaf extracts from diverse plant sources, such as eucalyptus, pomegranate, and cherry48. The presence of organic components, derived from the leaf extract, is indicated by a broad shoulder peak observed within the 15° to 30° range of 2θ values, suggesting their role as capping and stabilizing agents for the synthesized iron nanoparticles49. The XRD spectrum of FeNPs displays broadening diffraction and a lack of well-defined peaks, signifying the polydispersion of the nanoparticles, and the presence of multiple peaks at different angles suggests a variation in size. This pattern aligns well with the findings from the SEM images and PSA analysis. Notably, analogous FeNP patterns were observed in studies harnessing eucalyptus, pomegranate, and cherry aqueous extracts50,51.

Figure 4
figure 4

X-ray diffraction (XRD) pattern for the FeNPs.

SEM and PSA for biosynthesized FeNPs

The morphology, microstructure, and particle size distribution of the synthesized FeNPs were assessed using scanning electron microscopy (SEM) images and particle size analysis (PSA). SEM images of FeNPs synthesized with Vernonia amygdalina leaf extract at various magnifications are shown in Fig. 5a and b, revealing the successful synthesis of FeNPs. According to these images, the formed nanoparticles exhibit an irregular morphology and lack a uniform distribution in shape and size. By utilizing Image J software through SEM, the average particle size distribution of the FeNPs was estimated to be approximately 2.31 µm, as displayed in Fig. 5c and d. The analysis indicated that approximately 90% of the particles fell within the 1–4 µm range, while the remaining particles were outside this range. This result is consistent with that of a previous study on the biosynthesis of FeNPs from loquat Eriobotrya japonica leaves, which reported an average particle diameter of 114.3 nm and 0.114.3 µm52.

Figure 5
figure 5

SEM images (a and b); Histogram of PSA (c and d) in the biosynthesized FeNPs.

The biosynthesized FeNPs from the leaf extracts of Vernonia amygdalina were found to be polydispersed based on the XRD and UV‒Vis spectra, with a majority of them exhibiting a variable size with a smaller diameter. The results were confirmed by identifying size variation, with an average diameter of approximately 2.31 µm for the biosynthesized FeNPs, suggesting their relatively smaller size.

Evaluation of the catalytic activity of FeNPs for CV and MB dye degradation

Control experiment

Sodium borohydride is known to facilitate the reduction of crystal violet and methylene blue. However, when used in the absence of FeNPs, this process occurs slowly. As depicted in Fig. 6, after 60 min, only 25.10% and 15.73% of the crystal violet and methylene blue, respectively, were reduced. This is due to the large difference in redox potential between the donor and the acceptor, which makes the reduction thermodynamically favorable but not kinetically favorable. The addition of FeNPs as a nanocatalyst provides an alternative route with low activation energy for the reduction reaction, reducing the kinetic barrier and making the reaction kinetically favorable. Furthermore, the FeNPs provide a suitable surface for binding crystal violet and methylene blue particles and borohydride ions (BH4−1) to interact with each other, leading to the formation of decomposition products. These nanoparticles make the degradation of crystal violet and methylene blue kinetically feasible, resulting in complete reduction within a short period of time53,54.

Figure 6
figure 6

Degradation of CV and MB in the absence of 10 ppm initial FeNP concentration.

Effect of catalyst loading

To determine the optimal quantity of catalyst required for the efficient degradation of crystal violet and methylene blue, various concentrations of aqueous solutions containing the dyes at a concentration of 10 ppm were tested in the presence of varying amounts of the FeNP catalyst. The results, which are presented in Fig. 7 and ‘Tables S1 and S2’, indicated that the degradation efficiency increased as the amount of FeNP catalyst increased from 0.010 to 0.025 gm for crystal violet and from 0.010 to 0.075 gm for methylene blue. This can be attributed to the greater availability of surface active sites for BH4−1 ion and dye molecule adsorption with increasing FeNP dose37. Based on these findings, optimum catalyst loads of 0.025 gm for crystal violet and 0.075 g for methylene blue were identified, resulting in degradation percentages of 95.7% and 93.15%, respectively. It is worth noting that beyond the optimum catalyst load, the efficiency decreases due to the aggregation of nanoparticles at high catalyst doses, which may contribute to a lower degradation percentage by reducing the number of active sites55 and decreasing the electron density.

Figure 7
figure 7

Effect of catalyst loading on the degradation of CV and MB.

Initial concentration of dyes

The results of the present study, which involved examining six different concentrations of aqueous solutions containing crystal violet and methylene blue ranging from 5 to 30 ppm, are presented in Fig. 8 and Tables S3 and S4. The findings indicate that the degradation efficiency increased to an optimum value with increasing dye concentration from 5 to 20 ppm for crystal violet (97%) and from 5 to 15 ppm for methylene blue (93%). However, the rate of degradation decreased with a further increase in dye concentration, as this inhibited the electron transfer process on the nanoparticle surface between NaBH4 and the dye, thereby slowing down and reducing the number of active sites on the catalyst20.

Figure 8
figure 8

Effect of initial concentration on the catalytic degradation of CV and MB.

Effect of NaBH4 concentration

The concentration of NaBH4 was varied to determine the optimal concentration for degrading crystal violet and methylene blue while maintaining a fixed nanoparticle dose and dye concentration. The results revealed an increase in degradation with increasing NaBH4 concentration from 0.01 to 0.12 M, reaching a maximum efficiency at 0.12 M (Fig. 9, additional ‘Tables S9 and S10’). Hence, 0.12 M was identified as the critical concentration, highlighting the necessity of an appropriate BH4−1 ion concentration for optimal nanoparticle degradation. Moreover, the higher NaBH4 concentration elevated the local electron density on the FeNP surface, potentially leading to accelerated reaction rates56.

Figure 9
figure 9

Effect of sodium borohydride concentration on the catalytic degradation of CV and MB.

Effect of reaction time

The response over time (Fig. 10, see Tables S5 and S6) revealed that the degradation efficiency of both dyes increased with reaction time, peaking at 10 min for crystal violet (95.70% degradation) and 15 min for methylene blue (95.15% degradation). Beyond these durations, the efficiency plateau due to the active sites on the photocatalyst surface may become saturated or deactivated over time, suggesting that extended reaction times did not yield further enhancements in degradation efficiency57.

Figure 10
figure 10

Effect of reaction time on the catalytic degradation of CV and MB.

Effect of pH

The pH contributes to determining the acidity or basicity of a solution and is an important parameter affecting catalytic degradation. This study explored the optimization of pH levels within a range from 2 to 12 using initial concentrations of 20 ppm crystal violet, 15 ppm methylene blue, and 0.025 and 0.075 g of FeNPs. The results (Fig. 11, see Tables S7 and S8) revealed that the highest degree of crystal violet degradation (97.47%) occurred at pH 4, while the highest degree of methylene blue degradation (94.22%) occurred at pH 5. Subsequently, increasing the pH to 12 resulted in a gradual decrease in degradation percentages for both dyes (efficiency increases in acidic medium and decreases in basic medium), potentially due to the formation of ferrous hydroxide, which could have occupied active sites on the FeNPs, subsequently reducing their reduction capacity58.

Figure 11
figure 11

Effect of pH on the catalytic degradation of CV and MB under optimized conditions for all the other parameters.

Catalytic reduction and degradation of CV and MB

The reduction of dyes by FeNPs can be explained through the electron transfer effect. Iron, a good conductor, can facilitate the transfer of electrons between donors and receptors. Thus, this catalytic process is mediated by iron nanoparticles via a redox mechanism, allowing for the transfer of electrons from the donor (BH4) to the acceptors (CV and MB). As depicted in Fig. 12a, the reduction of dyes in the presence of FeNPs is initiated by NaBH4. Subsequently, with the assistance of FeNPs as a catalyst, electrons are transferred from BH4 to CV and MB, leading to the reduction of CV and MB into colorless and nontoxic LCV (leucocrystal violet) and LMB (leucomethyene blue), respectively, by removing chromophore groups such as azo, nitro, N–C and S–C conjugated systems, as indicated in Fig. 12b (see F1-SI for the detailed mechanism). The reduction of CV and MB by the FeNP catalyst in the presence of NaBH4 can be elucidated using the Langmuir–Hinshelwood model59. According to this model, the initially adsorbed BH4 ions donate electrons to the FeNPs (as shown in Eq. 1). As a result, a negatively charged layer develops around the FeNPs60. The reduction reaction at the FeNP surface is followed by the transfer of electrons from the FeNPs to cationic dye molecules through electrostatic interactions59. Previous work on PNP reduction by Ag/SiO2 NC catalysts has also shown that these catalysts adhere to the Langmuir–Hinshelwood mechanism61. This model involves both molecules adsorbing onto the catalyst surface before engaging in the bimolecular reaction. When NaBH4 is in excess, electrons and hydrogen are transferred to the surface of the nanocatalyst, where they control the rate of the reaction through the adsorption of dyes and borohydride ions (BH4) on the nanocatalyst surface.

$${\text{2BH}}_{{4}}^{ - } + {\text{FeNPs}} \to \left[ {{\text{FeNPs}}} \right]^{{{2} - }} + {\text{B}}_{{2}} {\text{H}}_{{6}} + {\text{H}}_{{2}}$$
(1)
Figure 12
figure 12

Schematic diagram of the catalytic reduction reaction (a) and mechanism of the catalytic degradation of CV and MB by the NaBH4 and FeNP samples (b).

The present study investigated the efficacy of an FeNP catalyst in the presence of NaBH4 as a reducing agent for the degradation of MB and CV dyes, which are commonly found in industrial effluents. The reduction process was found to be highly efficient, with removal efficiencies of 94.22% for MB and 97.47% for CV within 10 and 20 min, respectively, under optimized experimental conditions (Fig. 11). NaBH4 was preferred as the reducing agent due to its excellent electron-donating ability, facilitated by BH4 ions.

The cationic nature of the CV and MB dyes facilitated their strong attraction toward FeNPs, which generated a negative layer that facilitated quick electron transfer to the dye molecules. NaBH4 also serves as a source of hydrogen, which targets organic dyes after electron transfer to FeNPs. The resulting reaction produced reduced, colorless forms of methyl blue and crystal violet27. Subsequently, LCV and LMB desorbed spontaneously from the surface of the FeNPs and diffused into the solution due to weaker electrostatic interactions between the FeNPs and the colorless degradation products62.

Kinetics studies

In this study, various kinetic models were used to analyze the experimental data and determine the degradation mechanism of dyes. Specifically, three kinetic models were established: the pseudo zero-order, pseudo first-order, and pseudo second-order models. The degradation reactions were conducted under optimal experimental conditions at different time intervals ranging from 5 to 20 min while keeping all the other parameters constant. To investigate the pseudo kinetics, calibration curves were constructed, as depicted in Fig. 13. These curves were used to calculate the concentration of the dyes after degradation at different time intervals. The data for the calibration curves of crystal violet and methyl blue are presented in Table ‘S13’.

Figure 13
figure 13

Calibration curves of crystal violet and methylene blue.

Pseudo kinetic experiments were also conducted, and the data used for calculating the residual concentration of the dyes are presented in the table in ‘‘Table S14’’. From Table S14, the final concentrations of both dyes were calculated using their respective calibration curves, and other quantities used for investigating the pseudo kinetics were calculated and are shown in Table 1.

Table 1 Data for examining the pseudo kinetics of heterogeneous catalysis by FeNPs.

Pseudo zero-order, pseudo first order, and pseudo second order kinetic models

To investigate the degradation kinetics of crystal violet and methylene blue dyes by FeNPs, Eqs. (4), (5), and (6) were linearized and plotted as Co − Ct against time (t) and ln [Co/Ct] against time, and the plots 1/Co − 1/Ct versus time (t) were generated for the pseudo zero-order, pseudo-first-order, and pseudo-second-order kinetics models, respectively. Linear graphs with correlation coefficients for all the kinetics models are presented in Fig. 14a,b, and c. The correlation coefficients and rate constants for each kinetic model were calculated and are summarized in Table 2. According to the results of the analysis of pseudo zero-order kinetics, compared with the other models, the FeNPs exhibited high correlation coefficients close to unity (R2 = 0.999 and R2 = 0.995) for the degradation of methylene blue and crystal violet, respectively. These findings suggest that the degradation process best-fitting a pseudo zero-order kinetics model. Specifically, a pseudo zero-order reaction was observed when the surface of the catalyst reached saturation, and the degradation rate became independent of the dye concentration and remained constant over time. The results presented in Table 2 for pseudo-first-order kinetics reveal a relatively high correlation coefficient for only the catalytic degradation of methylene blue. These findings suggest that the catalytic degradation process occurring on the surface of the FeNP catalyst follows pseudo-first-order kinetics, where the rate of catalytic degradation and concentration of dye are directly proportional. Compared to those of other pseudo kinetic models, such as pseudo zero-order and pseudo-first-order models, the correlation coefficient of the pseudo-second-order model (as shown in Fig. 14c) is lower for both dyes. This indicates that the catalytic degradation of both dyes does not fit the pseudo-second-order model. In general, the high correlation coefficient suggested that the zero-order pseudo kinetic model is a suitable model for describing the degradation kinetics of both dyes by FeNPs. This finding is important because it indicates that FeNPs can be used as effective catalysts for the degradation of these dyes in wastewater.

Figure 14
figure 14

Pseudo zero-order (a), pseudo-first-order (b) and pseudo-second-order kinetic models for the catalytic degradation of CV and MB by FeNPs with NaBH4.

Table 2 Rate constant (k) and correlation coefficient (R2) calculated for the kinetic model.

Study of the reusability of iron nanoparticles

Currently, the reusability of catalysts is a significant issue because a large number of catalysts are deactivated after the first or second cycle and are subsequently discarded. The reusability and stability of catalysts are vital for determining their performance, as an active and stable catalyst could considerably decrease the cost of the process. Here, crystal violet and methylene blue were used to study the reusability of FeNPs under optimum experimental conditions. The reusability of the FeNPs was tested four times. Figure 15 and ‘‘Tables S11 and S12’’ show that the reusability of the FeNPs was good. The findings of this study indicate that the FeNPs synthesized through green methods were relatively stable and could serve as effective catalysts, with only a slight reduction in their degradation rate after being used four times. These results are consistent with those of a previous study in which amorphous FeNPs synthesized from an aqueous extract of Boswellia serrata, a renewable natural resource, were utilized. In that study, the FeNPs were found to retain their catalytic activity even after being recycled up to five times, with only a modest decrease in their effectiveness63. Thus, the results of both studies suggest that green synthesized FeNPs have the potential to be used as efficient and sustainable catalysts in various applications.

Figure 15
figure 15

Reusibility of FeNPs.

Materials and methods

Chemicals and reagents

The following analytical grade reagents were used directly as obtained without any further treatment throughout the work: ferric chloride, FeCl3 (99.99%, Sigma‒Aldrich, Indian) were used for the synthesis of iron nanoparticles as metal ion precursors. Crystal violet (AR, Samir Tech-Chem, Ltd., India) and methylene blue (AR, UniChem Ltd., India) dyes were used for the evaluation of the catalytic activity of the prepared iron and nanoparticles, and sodium borohydride, NaBH4 (97% extra pure Merck, India), ethanol, CH3OH (97% extra pure Sigma‒Aldrich, India), sodium hydroxide, NaOH (99.99%, Sigma‒Aldrich, India) and hydrochloric acid, HCl (37%, Sigma‒Aldrich, India) were used for adjusting the pH of the sample. Deionized water was used throughout the experiment to prepare the solutions, plant extracts and wash the plants.

Instrument and apparatus

A digital electronic balance (Model JA103P, China) with a 160 gm loading capacity was used to measure the leaf sample and all the other chemicals. A magnetic stirrer hot plate (UK) was used for stirring and maintaining the required temperature of the metal ion precursor and plant extract during the preparation of the iron nanoparticles. The extent of degradation of the dyes was monitored using a UV‒Vis spectrophotometer (CECIL CE1021, USA). After degradation, the dispersed iron nanoparticles were separated from the treated solution using an 80–2 centrifuge at a maximum speed of 5000 rpm. Fourier transform infrared spectroscopy (65 FT-IR Perkin Elmer Spectrum, USA), an ultraviolet‒visible spectrophotometer (SM-1600 spectrophotometer, USA), a powder X-ray diffractometer (Shimadzu XRD-7000S, Japan), and scanning electron microscopy (JEOL/EO-JCM-6000 plus, Japan) were used for characterization of the synthesized iron nanoparticles.

Preparation of Vernonia amygdalina leaf extract

The collection of plant material for this study was initiated after obtaining the necessary permit from the EWCA Hawassa town office, with permit number EWCA-H-TT0092/23. In accordance with the World Health Organization (WHO) Quality Control Methods for Medicinal Plant Materials collection and preparation procedures64, mature and healthy Vernonia amygdalina leaves were collected from Hawassa Tabor Mountain Wild Life Conservation and Repair Park in the Sidama Regional State, Ethiopia, which is approximately 251 km away from Addis Ababa. The plant was authenticated by Botanist Reta Regassa, and a voucher specimen with the number TT00129/23 was deposited at the HU Herbarium, Hawassa University, for future reference. The collected leaves were cleaned thoroughly using running tap water to eliminate debris and contaminants, followed by deionized water and air drying at room temperature for one week. The aqueous extract of the plant was prepared by grinding the leaves with a mortar and pestle and boiling them in deionized water at approximately 60 °C until the color of the aqueous solution changed to brown‒red (Fig. 16). The extract was cooled to room temperature and filtered using Whatman No. 1 filter paper. Finally, the extract was stored in a refrigerator at 4 °C for further experiments.

Figure 16
figure 16

Flow diagram for the preparation of the Vernonia amygdalina leaf extract.

Biosynthesis of iron nanoparticles (FeNPs)

Iron nanoparticles were synthesized as described previously65 with slight modifications (as shown in Fig. 17). Ferric chloride hexahydrate (FeCl3·6H2O) was used as the metal precursor. Then, 75 mL of the Vernonia amygdalina leaf extract was added dropwise to 75 mL of 0.1 M FeCl3·6H2O solution at a 1:1 ratio at room temperature. The resultant mixture was stirred using a magnetic stirrer for 5 min, and the formation of a grayish black solution confirmed the synthesis of the iron nanoparticles. The nanoparticles were separated by centrifugation at 5000 rpm for 15 min and cleaned by subsequent washing with ethanol and water 3 times. The synthesized iron nanoparticles were finally dried at room temperature and stored in a sealed tight container for further use.

Figure 17
figure 17

Flow diagram for the biosynthesis of FeNPs.

Characterization of synthesized iron nanoparticles

The synthesized iron nanoparticles were characterized using Fourier transform infrared (FT-IR) spectroscopy, ultraviolet‒visible (UV‒Vis) spectroscopy, powder X-ray diffraction (XRD) and scanning electron microscopy.

Catalytic degradation performance of iron nanoparticles

The catalytic activity of the synthesized iron nanoparticles was studied by degrading crystal violet and methylene blue in the presence of sodium borohydride as a reducing agent. To evaluate the effectiveness of the synthesized iron nanoparticles, an optimized amount of the synthesized nanoparticles was added following the addition of sodium borohydride to a beaker containing 25 mL of the prepared crystal violet and methylene blue aqueous solutions. A beaker containing a mixture of dye solution, sodium borohydride and nanoparticles was stirred on a magnetic stirrer. The mixture was subsequently centrifuged at 1500 rpm for 5 min to separate the nanoparticles from the degraded dye solution by preventing nanoparticle dispersion. The extent of degradation was monitored by measuring the absorbance before and after degradation at 590 and 664 nm for crystal violet and methylene, respectively.

Catalyst dose

For the optimization of the catalyst dose, catalyst doses ranging from 0.010 gm to 0.125 gm with a range of 0.025 gm were used per 25 mL of 10 ppm crystal violet and methylene blue at a constant value of the other parameter. Then, the catalytic degradation efficiency was calculated.

Initial concentration of dye

To investigate the effect of the initial concentration of dyes on the catalytic degradation efficiency, different initial concentrations of both dyes were tested (5, 10, 15, 20, 25 and 30 ppm for crystal violet and methylene blue). The catalyst dose was fixed at 0.025 gm/25 mL for crystal violet and 0.075 gm/25 mL for methylene blue. Prior to conducting these experiments, other parameters were optimized and applied while remaining constant.

Reaction time

To investigate the total reaction time required for the complete degradation of crystal violet and methylene blue, six trials were conducted with 5 min intervals between each trial. The catalyst dose was fixed at 0.025 gm/mL for crystal violet and 0.075 gm/25 mL for methylene blue, while the initial concentrations of crystal violet and methylene blue were fixed at 20 ppm and 15 ppm, respectively. Prior to conducting these experiments, other parameters were optimized and applied.

Concentration of sodium borohydride

The effects of the concentration of the reducing agent (NaBH4) on the degradation of crystal violet and methylene blue were investigated. To determine the optimum concentration of reducing agent for the best catalytic degradation, various concentrations of reducing agent were tested from 0.01 to 0.20 M. The catalyst dose was fixed at 0.025 gm/25 mL for crystal violet and 0.075 gm/25 mL for methylene blue, while the initial concentrations of crystal violet and methylene blue were fixed at 20 ppm and 15 ppm, respectively. Prior to conducting these experiments, other parameters were optimized and applied.

pH of dyes

To study the effects of pH on the degradation of both dyes, all the other parameters were kept constant, the pH was varied from pH 2 to pH 12, and the optimum pH was investigated.

Determination of degradation percentage

The degradation percentage of the dye solution was calculated by taking the absorbance values recorded at λmax values of 590 nm and 664 nm for crystal violet and methylene blue, respectively, before and after catalytic degradation. Equation (2) is provided as follows:

$$Degradation\,percentage = \frac{A0 - At}{{A0}} * 100$$
(2)

where Ao = the initial absorbance of the dye solution before exposure to sunlight and At = the absorbance of the dye solution at time (t).

Kinetics study

In this investigation, all the measurements were performed under optimized experimental conditions. Calibration curves were constructed for both dyes to calculate the concentrations of the dyes after degradation at different time intervals. Then, a constant concentration (initial concentration with high degradation efficiency) was used for both dyes, and the extent of degradation was studied within 5 min intervals. The concentration of dye was subsequently calculated by applying the Beer–Lambert law, as shown in Eq. (3):

$$A = \in bC$$
(3)

where A—Absorbance, —Molar absorptivity constant, b—Path length, C—Concentration.

This equation is related to y = mX + b, and from the absorbance versus concentration data, the slope (m) was calculated and used to calculate the concentration after degradation. Finally, pseudozero-order, pseudo-first-order and pseudo-second-order kinetics were investigated according to Eqs. 4, 5 and 6, respectively, as mentioned below.

$$C{\text{o}} - {\text{C}} = k_{0} {\text{t}}$$
(4)
$$ln\frac{{C_{o} }}{{C_{t} }} = k_{1} t$$
(5)
$$\frac{1}{C} - \frac{1}{{C_{o} }} = k_{2} t$$
(6)

Instrumental calibration

Standard stock solutions of dyes were taken for calibration of the instrument for dyes used for the experiment. For instrument calibration, first, 1000 ppm stock solution of each dye was prepared, and an intermediate standard solution containing 100 ppm was prepared in a 500 mL volumetric flask. The intermediate standards were subsequently diluted with deionized water to obtain six working standards for each dye of interest for calibration purposes.

Study on catalyst reusability

The reusability of the catalyst was investigated during the degradation process under identical experimental conditions (at the optimum concentration of dye solution, reducing agent, catalyst dose, and time). After the completion of the reaction, the catalyst was separated by centrifugation from the reaction mixture, washed with ethanol and water, dried and reused for four consecutive cycles.

Conclusion

Iron nanoparticles (FeNPs) were successfully synthesized by a green method using Vernonia amygdalina plant leaf extract as a natural reducing and capping agent. The process is relatively easy, fast, cheap, and environmentally friendly and does not require any organic solvents or other toxic reagents. Biosynthesized FeNPs were characterized with different analytical techniques, such as UV‒visible, FT-IR, XRD, and SEM, and the obtained instrumental analysis data revealed continuous absorption at the SPR in the visible range, suggesting the formation of amorphous FeNPs, the presence of various functional groups, indistinct diffraction peaks that reveal predominantly amorphous FeNPs and irregular morphology with a lack of uniform distribution in shape and size and an average particle size distribution of approximately 2.31 µm. The biosynthesized FeNPs were also applied for the catalytic degradation of MB and CV in the presence of NaBH4 and showed maximum catalytic degradation efficiencies of 94.22% and 97.47%, respectively, under optimum conditions for each dye. The kinetics study exhibited high correlation coefficients close to unity (0.999 and 0.995) for the degradation of MB and for the degradation of CV, respectively, for the zero-order pseudo kinetics model, which indicates that the model is highly suitable for the degradation of both dyes by FeNPs compared to other models. The reusability and stability of the biosynthesized nanocatalysts were studied, and the catalysts were successfully used as efficient catalysts, with a slight decrease in the degradation rate of more than four times. The results from this study showed that the use of biosynthesized FeNPs is a cost-effective, environmentally friendly, and efficient means for the highly efficient catalytic degradation of toxic pollutant dyes discharged from industries such as medicine, cosmetics, paints, plastics, and textiles.