Green Synthesis of Ag-Au Bimetallic Nanocomposites Using Waste Tea Leaves Extract for Degradation Congo Red and 4-Nitrophenol

Abstract

A sustainable supply of pure water is a great challenge in most developing and third-world countries. Nanomaterial-based technology offers technological development for wastewater purification. Nanocatalysis hydrogenation of nitroarene and dye molecules is a hot model in many research fields. Herein, we report eco-friendly and facile technology to synthesize Ag-Au bimetallic nanocomposites. The synthesized nanocomposites are characterized by ultraviolet–visible spectroscopy, Fourier-transform infrared spectroscopy, X-ray diffraction, field emission scanning electron microscopy and high-resolution transmission electron microscopy. The synthesized nanocomposite can efficiently degrade Congo red and 4-nitrophenol in water and in the presence of sodium borohydride. The results show that it degrades Congo red and 4-nitrophenol entirely within 6 and 7 min, respectively. These results could be useful for the green synthesis of Ag-Au bimetallic nanocomposites and help to remove organic dye molecules and nitroaromatics from wastewater.

1. Introduction

Aromatic compounds that contain a benzene ring, one or more hydroxyl group(s), one or more nitro group(s) and one or more azo bond(s) are toxic to the environment [1]. Nitrophenol compounds have broad industrial applications in dye, herbicide, pesticides, drugs and explosives [2]. One of the toxic, polluting agents is 4-nitrophenol, which causes headaches, drowsiness, stomach pain, chest pain and vomiting and damages organisms [3]. Furthermore, the dye compound contains a benzene ring and azo bonds and is used in textile industries, dyeing cotton, rubber, paper, paint and many other products [4]. The majority of dye molecules are harmful to human health and marine organisms, even at low concentrations [5]. Allergic dermatitis, skin allergy and dysfunction of the sex organs, kidney, brain, liver, etc., are caused by toxic dye molecules [6,7,8]. Moreover, wastewater containing colored substances prevents the penetration of oxygen and sunlight, which are needed for the survival of aquatic forms [9]. Congo red (1-naphthalene sulfonic acid, 3,3-(4,4-biphenylenebis(azo) bis(4-aminodisodium) salt) is a toxic anionic azo dye [4]. The complex molecular structures of Congo red dye inhibit degradation [10]. Thus, industrial wastewater containing 4-nitrophenol and dye molecules must be treated before discharge into a river or seawater. In the treatment of wastewater effluents, different techniques have been applied that are inexpensive, effective and eco-friendly for the detoxification of synthetic dyes and 4-nitrophenol [11,12,13,14,15,16,17]. Among the various treatment technologies, catalytic hydrogenation in the presence of sodium borohydride has been intensively investigated [18,19]. This model of catalytic hydrogenation reaction has been used widely due to the simplicity, cost-effectiveness and lower toxicity of NaBH₄ and because it is easily monitored by UV–Vis spectroscopy [16,20]. Moreover, the conversion of 4-nitrophenol to 4-aminophenol has great profit-making potential because 4-aminophenol is used as an important intermediate for the synthesis of the antipyretic drug paracetamol [21]. The azo bonds in azo dye molecules can be cleaved easily using catalytic hydrogenation, and the dye molecules transform into less toxic and eco-friendly products. Different researchers have applied various catalytic systems for rapid hydrogenation of 4-nitrophenol and azo dye molecules in the last decade [20]. However, many of the surfactants and reactants used in these processes are toxic to human beings and the environment [20,22]. Thus, we should use green methods for the synthesis and application of metal nanoparticles [23]. Researchers have applied different flower extracts, leaf extracts and fruits to synthesize gold and silver nanoparticles in recent years [16,19,24,25,26,27]. The green synthesis of gold and silver nanoparticles using the most commonly available tea leaves extract is reported [28,29]. Tea leaves are among the most popular food and beverage ingredients with the highest flavonoid content, resulting in high antioxidant activity. The phytochemicals and amino acids found in tea leaves are responsible for reducing silver and gold ions [30,31]. Besides, the synthesis of bimetallic nanostructures and their catalytic activity are hot topics nowadays [27]. In recent years, Tripathy et al. reported on the synthesis of Ag-Au bimetallic nanocomposites using a biodegradable synthetic graft copolymer, hydroxyethyl starch-g-poly (acrylamide-co-acrylic acid), as well as the study of their catalytic activities [32]. Bimetallic catalysts exhibit unique catalytic activities relative to their parent metals, which provide the ability to create new catalysts with better activity and selectivity [32,33]. The catalytic activity of metal nanoparticles relies significantly on their preparation methods, which control their size, shape and morphologies [32]. Green synthesis of bimetallic nanocomposites using green molecules would be more feasible and environmentally sustainable. Therefore, the synthesis of Ag-Au bimetallic nanocomposites using waste tea leaf extract is of interest in this paper. Furthermore, the synthesis of Ag-Au bimetallic nanoparticles/nanocomposites using waste tea leaf extract has not yet been reported.

Herein, we report an easy and facile synthesis approach of Ag-Au bimetallic nanocomposites using waste tea leaves extract to perform catalytic hydrogenation reaction of 4-nitrophenol (4-NP) and Congo red (CR) dye molecules in water.

2. Materials and Methods

2.1. Materials

Chloroauric acid tetrahydrate (HAuCl₄·4H₂O), silver nitrate (AgNO₃), sodium borohydride (NaBH₄), 4-nitrophenol and Congo red dye were purchased from Sigma-Aldrich Chemicals Company, Seoul, Korea. Waste tea leaves were collected from India. Double-distilled water was used in all the experiments.

2.2. Preparation of Waste Leaves Extract

The collected tea leaves were washed with distilled water to remove dust particles if present. Then, 1.0 g of washed tea leaves was taken into a 250-mL beaker with 100 mL of distilled water. The beaker was put on a hotplate with a magnetic stirrer at 80 °C for 10 min. Then, the beaker was kept at room temperature to settle down its contents. Following this, the tea color solution was filtered using Whatman 42 filter paper. The filtrate was collected in a sterile 100-mL conical flask and was ready for immediate use or kept at 4 °C for later use.

2.3. Synthesis of Ag-Au Nanocomposites

The typical synthesis process for Ag-Au bimetallic nanocomposites (Ag-Au NCPs) was as follows: First, 40 mL of 10⁻³ (M) silver nitrate and 50 mL of 10⁻³ (M) chloroauric acid tetrahydrate were mixed in a 250-mL beaker. Then, 3.0 mL of 50% diluted tea extract from the stock solution was added into the beaker by drops at room temperature. The immediate color change of the solution was observed and its intensity increased significantly over time and finally changed to reddish brown, as shown in Figure 1. The entire reaction process was carried out in the absence of sunlight to avoid any parent solution decomposition or nanocomposites. Silver nanocomposites (Ag NCPs) and gold nanocomposites (Au NPCPs) were prepared separately under the same experimental conditions to compare the color difference with Ag-Au NCPs. The schematic representation of the synthesis process and catalytic activities of Ag-Au NCPs is shown in Figure 1.

2.4. Reduction of 4-Nitrophenol and Congo Red Azo Dye

The reduction of 4-NP to 4-AP was carried out in a UV quartz cuvette with a length of 1 cm and a volume of 2.5 mL. The cuvette took 1.5 mL of 10⁻⁴ (M) 4-NP water solution, and 20 µL NaBH₄ methanol solution (prepared with 2 mg 4-NP and 5 mL of distilled methanol) was added. After that, 20 μL of Ag-Au NCPs hydrosol was mixed into the mixture and the catalytic activity was studied by kinetic analysis using UV–Vis spectroscopy. The spectrum was measured at an interval of 1 min at a wavelength of 600–200 nm. Furthermore, the degradation of 1.5 mL of 10⁻⁴ (M) Congo red solution was followed by a similar procedure and the spectrum was taken at a wavelength of 800–200 nm at an interval of 1 min.

2.5. Material Characterization

For optical, morphological and structural analyses, the synthesized nanocomposites were characterized by different characterization techniques. Colloidal samples were used for optical properties’ investigations by UV-Vis spectroscopy (Shimadzu 1800, Shimadzu, Tokyo, Japan) and absorbance spectra were measured in a 1-cm quartz cuvette with a wavelength of 800–200 nm. A Perkin Elmer (Spectrum Two, Beaconsfield, UK) spectrometer was used to measure FT-IR spectra using KBr pellets in wavelengths from 4000 to 400 cm⁻¹ to investigate changes in chemical functionality. Ag NCPs, Au NCPs and Ag-Au NCPs were first centrifuged, and then, the solid residue was dried in a vacuum oven at 60 °C. For the structural investigation, an X-ray diffractometer (Miniflex, Rigaku, Japan) was used to obtain the spectrum of bimetallic nanocomposites using Cu Kα radiation at a scan rate of 1° min⁻¹ in the range of 5–80°. The thick film of Ag-Au NCPs was produced by drying the colloidal sample onto a clean glass substrate for XRD measurements. Field emission scanning electron microscopy (FESEM, Gemini 500, Carl Zeiss) and high-resolution transmission electron microscopy (HR-TEM, JEM-2200 FS, JEOL Ltd., Japan) at 200 kV were used for morphological investigation. Again, the drop-casting technique was used to obtain sufficient material for SEM analysis on glass substrates and HR-TEM analysis, using a lacey F/C 300 mesh Cu grid.

3. Results and Discussion

A color change was observed with the formation of Ag-Au NCPs from yellowish to reddish brown. The distinct color change of the colloidal solution of the Ag-Au NCPs compared to the Ag NCPs and Au NCPs indicates the formation of the Ag-Au NCPs. The UV–Vis spectra of nanocomposites’ hydrosols are shown in Figure 2.

The absorbance peak at 412 nm of the Ag NCPs and the peak at 530 nm of the Au NCPs suggest the formation of silver and gold nanocomposites. The well-defined peak at 433 nm is due to Ag-Au bimetallic nanocomposites, which is different from the peak positions of Ag and Au NCPs. By simple mixing of the Ag NCPs and Au NCPs, the SPR band at 433 nm was not obtained. Therefore, this result indicates that the absorbance band at 433 nm is due to the SPR band of Ag-Au bimetallic nanocomposites.

FT-IR spectra of waste tea samples and synthesized metal nanocomposites are shown in Figure 3 and the peak details are shown in

Table 1. The FT-IR peak details of tea and monometallic and bimetallic nanocomposites.

Sl No	IR Peak at (cm−1)				Assignment
	Tea	Ag NCPs	Au NCPs	Ag-Au NCPs
1.	3380	3459	3442	3428	–OH stretching
2.	2926	2928	2918	2928	–CH2 asymmetric stretching
3.	1637	1637	1637	1637	C=O stretching vibration
4.	1454	1543	1543	1543	-CH2 bending, ring stretch, C=C, C-O
5.	1238	1385	1396	1385	-C(O)-O stretching vibration and –OH in plane vibrations
6.	1149	1116	1116	1116	-C-O stretching of 2° alcohols
7.	1043	….	….	….	-C-O-C, anhydride, stretching

.

FT-IR spectrum of the tea sample shows a distinct difference from that of Ag-Au NCPs, Ag NCPs and Au NCPs.

The peak values of different functionalities are shifted to various frequencies. The peak at 1454 cm⁻¹ is shifted to 1543 cm⁻¹, the peak at 1238 cm⁻¹ to 1385 cm⁻¹ and the peak at 1149 cm⁻¹ to 1116 cm⁻¹ with increasing intensity due to the formation of nanocomposites with amide and −OH functionalities. Some more peaks also appeared that suggest the formation and stabilization of monometallic and bimetallic nanocomposites by waste tea leaves extract.

Figure 4 shows the wide-angle XRD patterns of Ag-Au nanocomposites. The diffractogram revealed the existence of distinct characteristic Ag-Au bimetallic peaks and cellulose peaks. The intense peak of Ag-Au NCPs is obvious at 2θ angles 38.2°, 44.2°, 64.4° and 77.1°, most of which confirm the findings of previous works [34,35,36]. Others amorphous and crystalline peaks suggest cellulose crystallinity of tea leaves [37]. This result supports the formation of Ag-Au bimetallic nanocomposites by waste tea leaves extract.

FESEM and HR-TEM were used to recognize the surface morphology and size of Ag-Au NCPs, and EDS analysis was carried out to know the atomic percentage of Ag and Au in the bimetallic nanocomposites as shown in Figure 5. FESEM and HR-TEM micrographs (Figure 5a,b,d) show the spherical shape of Ag-Au nanoparticles in capping with shades in prickly pear (Opuntia).

The shades on the nanocomposites’ surface indicate the secondary materials, which are the phytochemicals of tea leaf extract [28,38]. It should be noted that these phytochemicals (mostly carboxylic acids) can efficiently reduce silver and gold to nanoparticles and act as a suitable capping agent, thus preventing them from aggregating [28,38]. The selected area electron diffraction (SAED) pattern (Figure 5f) displays that the Ag-Au nanocomposites are crystalline, and the crystalline ring represents the different lattice arrangement (Figure 5e). The EDS spectrum represents the Ag and Au’s presence in Ag-Au NCPs at 2–3 and 8–12 keV, respectively. Bimetallic nanocomposites contain a higher amount of Ag than the Au content. The higher content of Ag in bimetallic nanocomposites was explained by the fact that Ag(I) ions attract more carboxylate groups than AuCl₄⁻ ions due to the smaller size of Ag(I) ions over larger AuCl₄⁻ ions [32].

The degradation in the presence of Ag-Au NCPs and NaBH₄ of the Congo red dye molecules is shown in Figure 6a. Usually, the presence of azo bonds in the dye molecules is not reduced by NaBH₄, but there is a reduction in metal nanoparticles’ presence. The UV–Vis spectra of the Congo red dye’s degradation display the appearance of two absorbance bands at 490 and 342 nm due to the n→π^* and π→π^* electron transitions associated with azo bonds (-N=N-). It is apparent from the figure that the intensity of both absorption peaks significantly decreases over time, and the color of the Congo red solution becomes colorless after 6 min.

The UV–Vis spectra of the reduction of 4-NP to 4-AP by Ag-Au NCPs in the presence of NaBH₄ are shown in Figure 6b. The sharp absorbance peak at 401 nm gradually decreases over time due to the reduction of 4-NP. The new absorbance peak at 292 nm rises simultaneously due to the formation of 4-AP, and the reaction is completed in 7 min. Rapid degradation of Congo red dye molecules and 4-NP occurs due to the greater surface area and irregular facets of the Ag-Au bimetallic NCPs. The mechanism of the azo bond cleavage and the reduction of 4-NP by Ag-Au NCPs in the presence of NaBH₄ have been explained in detail in our previous articles [16,32] as well as in Figure 7. Besides, the reusability of bimetallic Ag-Au nanocomposites in the hydrogenation reaction of Congo red and 4-nitrophenol was studied based on previous studies [32]. The catalyst obtained in this study was used in the hydrogenation reactions, and after four cycles, it still displayed significant activity. These results indicate that the green synthesis of Ag-Au bimetallic nanocomposites provides greater stability and catalytic activity.

4. Conclusions

Ag-Au bimetallic nanocomposites’ green synthesis was carried out by a facile method using waste tea leaves extract in the water medium. The phytochemicals of the tea leaves extract act as a reducing and stabilizing agent. Ag-Au nanocomposites’ formation was described based on extensive characterization results such as UV–Vis, FT-IR, XRD, FESEM, HR-TEM and EDS. The synthesized Ag-Au NCPs were used to study their performance as a bimetallic nanocatalyst in the degradation of Congo red dye molecules and 4-nitrophenol in the presence of NaBH₄. The complete reduction in azo bonds and nitro groups occurred within 6 and 7 min, respectively. The easy synthesis method and high catalytic activity of bimetallic Ag-Au nanocomposites could be useful for the removal of dyes and nitroaromatics from industrial effluent/wastewater purification.