Green Method for Synthesis of Gold Nanoparticles Using Polyscias scutellaria Leaf Extract under UV Light and Their Catalytic Activity to Reduce Methylene Blue

The aqueous fraction of Polyscias scutellaria leaf extract (PSE) has been used as a reducing agent and stabilizer in the green synthesis of gold nanoparticles (AuNPs). UV-Vis spectrophotometry, particle size analyzer (PSA), Fourier transform infrared (FTIR) spectroscopy, transmission electron microscopy-selected area electron diffraction (TEM-SAED), and X-ray diffraction (XRD) were used to characterize AuNPs. The AuNPs have a size of 5–20 nm and have a face centered cubic (fcc) crystal structure and are stable for 21 days. Phenolic compounds, which are secondary metabolites of PSE, act as an active compound to reduce Au ion to Au, as well as stabilize the AuNPs through their surface interaction with carbonyl and hydroxyl groups of phenols. AuNPs exhibit excellent catalytic activity for the reduction of methylene blue with NaBH 4 . The reduction of methylene blue using AuNPs catalysts is a pseudo-first-order reaction with a reduction rate constant (kobs) of 0.0223min.


Introduction
In recent years, research on the synthesis of nanoparticles using green materials, commonly called green synthesis, has been growing.The proposed materials are types of microorganisms, enzymes, plants, or plant extracts [1].The reported biological resources can be used as a reducing and stabilizing agent in the synthesis of metal nanoparticles [2][3][4][5].
The role of plants in the synthesis of metal nanoparticles depends on the content of secondary metabolites.Specific plants contain specific chemical compounds which can act as active substances in the process of reduction and stabilization of nanoparticles.These compounds are alternative environmentally friendly materials in nanoparticle production due to their function to reduce the use of hazardous chemicals, including wastes [6].Biomolecules in plant extracts that can reduce metal ions into nanoparticles include proteins, polysaccharides, alkaloids, flavonoids, terpenoids, and phenolic acids [7,8].
Several studies of green synthesis have used the extracts of J. sambac leaf [5], Rosa rugosa leaf [9], Magnolia kobus and Diospyros kaki leaves [10], Ocimum sanctum leaf [11], Aerva lanata leaf [12], Coriandrum sativum leaf [13], Phyllanthus [14], and henna leaf [15] as reducing agents in AuNPs synthesis.On the other hand, Indonesia has abundant natural resources, including a biological diversity [16][17][18][19].Many types of plants can be explored and used as a nanoparticles green synthesis material.One of the plants which is easily found in Indonesia and has not been reported as a nanoparticles synthesis material is Polyscias scutellaria.Polyscias scutellaria leaves contain alkaloids, saponins, flavonoids, and polyphenols [20].Therefore, Polyscias scutellaria leaf is an appropriate choice as a reducing and stabilizing agent in green synthesis of AuNPs.
AuNPs are interesting to study, especially their catalytic properties [21][22][23][24][25], due to their excellent stability.They have been known as excellent catalysts in redox reactions due to their large surface area.In a previous study, AuNPs have been widely used as a good catalyst in reducing methylene blue (MB) in the presence of sodium borohydride (NaBH 4 ).The existence of AuNPs as a catalyst makes the reduction of MB run faster [26].
In this work, AuNPs were synthesized using Polyscias scutellaria leaf extract (PSE) with the assistance of UV radiation.Moreover, reduction of MB was used as a model reaction to evaluate the catalytic activity of AuNPs.

Experimental
2.1.Chemicals and Materials.Polyscias scutellaria was obtained from Tegalwaru, Bogor, and has been determined at LIPI, Bogor, West Java, Indonesia.NaBH 4 and methylene blue were obtained from Merck.Methanol, n-hexane, and ethyl acetate were obtained from PT. Brataco.HAuCl 4 solution used in this research was synthesized by dissolving 99.99% of pure Au metal (PT Antam) in aqua regia (HNO 3 : HCl = 1 : 3) solution.All chemicals were of analytical grade and were used without further purification.MilliQ water (18.2Ω cm −1 ) was used to make aqueous solutions.

Preparation of Polyscias scutellaria Leaf Extract.
Five kilograms of Polyscias scutellaria leaves was washed with water and dried in the open air.50 g of dried Polyscias scutellaria leaf powder was macerated in 250 mL of methanol for 7 days.The mixture was filtered to obtain a greenish concentrated solution.It was partitioned using n-hexane with the volume ratio of 1 : 1.The methanol fraction was collected and concentrated using a vacuum rotatory evaporator at 50 ∘ C. It was repartitioned using water and ethyl acetate solvents in a volume ratio of 1 : 1.The final water fraction of Polyscias scutellaria leaf extract (PSE) was then collected and concentrated using a vacuum rotatory evaporator.The water fraction of PSE was tested phytochemically and characterized using FTIR spectroscopy (Prestige 21, Shimadzu) to determine the content of secondary metabolites for the synthesis of AuNPs.

Catalytic Activity of AuNPs.
The mixture of 4.0 mL of 3.0 × 10 −5 M methylene blue and 0.5 mL of 0.1 M NaBH 4 solution was added to AuNPs colloid as a catalyst at various volumes of 50-150 L or equivalent to the concentration of 1.10-3.23%(v/v).The mixture was shaken and its reaction was observed through absorbance change using a UV-Vis spectrophotometer against reaction time for 30 minutes.[26].Therefore, the active compound in the aqueous PSE indicated a type of flavonoid compounds.

PSE Concentration Effect in AuNPs
Synthesis.AuNPs were synthesized using PSE under UV radiation for 2 hours due to containing less active compounds at room conditions.Therefore, the higher energy of UV light is required to excite the electrons in the active compound for reducing Au 3+ to Au 0 .AuNPs formation was observed through the color changes from yellow to pink at  max of 510-580 nm [27].AuNPs synthesis was conducted in various concentrations of PSE to determine the optimum concentration for reducing and stabilizing AuNPs.The higher the concentration of PSE, the more intense the color of the colloid generated in the system, due to the increase of the reducing agent.However, in high concentrations of PSE, faster growth of AuNPs core occurred, causing an increase in the nanoparticles collisions frequency to form agglomeration.
The optimum concentration of PSE in AuNPs synthesis was indicated from the high absorbance value, smallest maximum wavelength ( max ), and sharpest peak shape.Absorbance indicates the amount of substance to absorb light.Wavelength indicates the amount of energy needed by nanoparticles to conduct surface plasmon resonance (SPR).The great size of nanoparticles results in a smaller bandgap.Therefore, the energy required to conduct electronic transition was getting smaller and  max shifted towards a higher value.Sharp    formed nanoparticles have a homogeneous size.The UV-Vis absorption spectra of AuNPs formation against various PSE concentrations are shown in Figure 2. The optimum concentration of PSE in AuNPs synthesis was 0.01% (w/v), and AuNPs had a good stability for 21 days observed at  max of 532-534 nm as shown in Figure 3.The observation of stability after 21 days showed larger  max shift and a significant decrease of absorbance, indicating the occurrence of agglomeration [28].a single peak, 15.49 nm.The resulting size indicated that the PSE had sufficient strength to reduce Au 3+ to Au 0 .This was also confirmed from the zeta potential value of −19.6 mV that explained the charge of PSE stabilizer capped AuNPs surface (Figure 5).The more negative the zeta potential value, the more frequent the interparticle repulsion, so that the particle becomes more stable [29].It is concluded that the PSE is a good stabilizing agent for AuNPs.

FTIR Analysis. FTIR characterization was conducted to
investigate the interaction between functional groups of PSE and AuNPs in the PSE capped AuNPs.FTIR spectra show the wavenumber shift of PSE functional groups before and after AuNPs formation as shown in Figure 6.The vibrations of the -OH group shifted from 3371 to 3427 cm −1 and those of the C=C aromatic group shifted from 1609 to 1634 cm −1 .These small shifts are due to the interaction of functional groups (-OH and C=C) in PSE compounds on AuNPs surface.This indicates that AuNPs are capped by the flavonoids in PSE.The oxidation of flavonoids in aqueous solutions under UV light may produce keto forms and act as a reducing agent for Au 3+ to Au 0 [26,30].

TEM-SAED Analysis. TEM-SAED characterization was
conducted to observe the morphology, particle size, and crystal structure of AuNPs. Figure 7 shows the TEM images of the synthesized particle with a magnification of 150,000x.The morphology of AuNPs was spheres with a diameter of 5-20 nm.It was in accordance with the result of PSA characterization.

Catalytic Activity of AuNPs for the Methylene Blue
Reduction.The catalytic activity of the synthesized AuNPs was tested in the reduction of methylene blue by NaBH 4 .Reduction of methylene blue was observed from the fading of blue color solution due to the decrease of UV-Vis absorption spectrum at  max of 664 nm [32,33].In comparison, in the same circumstances, methylene blue was reacted with NaBH 4 in the absence of AuNPs catalyst and showed a very small decrease in absorbance of methylene blue as shown in Figure 10.
The reduction reaction was as follows: The reaction was assumed to follow pseudo-first-order kinetics.It used the excess concentration of NaBH 4 compared to the concentration of methylene blue, so the concentration of NaBH 4 was considered to be fixed during the reaction.The pseudo-first-order rate constant was calculated from the ( The plotting results of ln(  / 0 ) versus reaction time () in various concentrations of AuNPs are shown in Figure 10.

Conclusion
The AuNPs were successfully synthesized using a cheap and environmentally friendly route.PSE can be effectively used as reducing agent and stabilizer to produce AuNPs with diameters of 5-20 nm and stable for 21 days.The synthesized AuNPs were then used as a reduction catalyst of methylene blue in the presence of NaBH 4 .It was found that AuNPs are able to play a role as good catalysts with a pseudo-first-order rate constant of 0.0223 min −1 .AuNPs synthesis through this green method can contribute to the other fields such as green photocatalyst, drug delivery, antimicroorganism, adsorbent, detector, and green separation science and technology.

Figure 7 :
Figure 7: TEM images of synthesized AuNPs with a magnification of 150,000x.

3. 6 .
XRD Analysis.XRD characterization was conducted to determine the crystallinity of AuNPs to support the data of TEM-SAED.Typical diffractogram peaks of AuNPs were determined by comparing the value of diffraction angle (2) against JCPDS Au data as shown in Figure9.From the results, there are some peaks of 2