Document Type : Research Paper
Authors
1 Chemistry Department, College of Education for Pure Sciences (Ibn Al – Haitham), University of Baghdad , Baghdad , Iraq
2 College of science for women, university of Babylon, Iraq
3 Chemistry Department, College of Science Diyala University, Iraq
4 National Research Ogarev Mordovia State University, Republic of Mordovia, Saransk, Russia
5 Department of Pharmacology, Saveetha Dental College and Hospital, Saveetha institute of medical and Technical Sciences, Saveetha University, Chennai, India
6 Kazan State Power Engineering University, Kazan, Russia
Abstract
Keywords
INTRODUCTION
Energy consumption is one of the critical challenges of humanity [1]. Industrialism has imposed some harmful effects including environmental and energy-based drawbacks. The mentioned challenges are crucial for human life and play a key role in the economy, policy, and national security. Till now, many efforts have been focused on the balancing of these drawbacks [2, 3]. One of the most prominent methods which is developed is the photocatalytic process. A photocatalyst is a material that absorbs light and converts it to a higher energy level before passing it on to a reacting product to degrade different organic pollutants [4-6]. So, the photocatalyst uses solar energy as a renewable energy source to solve the environmental issue. The photocatalytic process is the intersection of energy and environment [7, 8]. The emergence of nanoscience leads to utilizing nanoscience and nanotechnology to overcome energy and environment-based challenges. Till now, various nanostructures have been applied for overcoming these challenges [9-12].
GQDs have recently become the subject of study due to their interesting luminescence properties that are size-dependent. This distinguishes it from other carbon derivatives. GQDs can be defined as very tiny size graphene fragments which cause quantum confinement in GQDs [13-15]. This characteristic makes GQDs biocompatible, photostable, high quantum efficiency, and chemically inert [16]. Next to this, GQDs can be synthesized via a simple method and low-cost precursors [17]. These excellent properties lead to the application of GQDs in the photocatalysis-based application. GQDs suffer from various limitations such as a strong tendency of aggregation, and the difficulty of recovery and reusability. To overcome these problems, other nanomaterials can be used alongside GQDs [14, 18, 19]. Co3O4-based nanostructures are a good candidate for the improvement of the photocatalytic activity of GQDs. Cobalt oxide is widely used as magnetic material, catalyst and photocatalyst, antibacterial agent, and drug delivery. The use of Co3O4 causes easily magnetically separation from the reaction system. Since the physical and chemical properties of Co3O4 nanomaterials are tunable, they can be synthesized in any size and shape depending on the application field [20-22].
Chun-Hui Shen and et al. prepared Co3O4/CeO2 nanocomposites by a simple chemical reaction, followed by annealing in a muffle furnace. They applied prepared nanocomposites to activate peroxymonosulfate (PMS) for ciprofloxacin (CIP) degradation. They reported that the 5 wt% Co3O4/CeO2/PMS showed the highest degradation efficiency of CIP (87.8%) under visible light irradiation. The prepared Co3O4/CeO2/PMS system still provided a sufficient catalytic activity in presence of different anions [23].
In another work, Co3O4/red phosphorus (Co3O4/RP) photocatalyst was prepared via a hydrothermal and mechanically grinding route. The findings revealed that Co3O4 nanocrystals were mounted on the RP’s surface. When compared to pure RP, the addition of Co3O4 to the RP improved light absorption. It is found that under visible light, 94.5% of malachite green (MG) can be photodegraded within 20 min via 10% Co3O4/RP composite, while only 17.3% and 59.9% of MG can be photodegraded via pure Co3O4 and RP [24].
In this work, novel Co3O4/SN-GQDs nanocomposites were synthesized via a simple and facile hydrothermal method. The prepared products were characterized with XRD, FTIR, SEM, TEM, and UV-Vis analysis. Then, the prepared nanomaterials were applied as a photocatalyst for the degradation of organic pollutants under visible irradiation.
MATERIALS AND METHODS
Chemical and reagents
Cobalt nitrate (Co (NO3)2.6H2O), Polyvinylpyrrolidone (PVP), sodium hydroxide (NaOH), citric acid, and L-cysteine were purchased from Merck and all the chemicals were used as received without further purifications.
Synthesis of SN-GQDs
SN-GQDs was prepared according to a previously published paper [25]. In brief, citric acid and L-cysteine, 1:1 molar ratio, were dissolved in 10 mL distilled water and heated for 6 hours at 90 °C in an oil bath. Then, the obtained viscous gel was transferred to stainless autoclave and heated to 180 °C for 6 h. The obtained product was diluted with 200ml distilled water and centrifuged at 12000 rpm for 30 min. The obtained solution was kept at 4°C for further tests.
Preparation of Co3O4 nanoparticles
In a typical procedure, 2 mmol (0.58g) of Co (NO3)2.6H2O and 0.5g PVP were dissolved in 20 ml distilled water. Then, NaOH (2M) was added dropwise to the Co-containing solution. Then, the solution was transferred to stainless autoclave and heated at 120 ˚C for 20 hours. The prepared product was centrifuged at 12000 rpm for 30 min. The collected solid was washed with ethanol and water for several times. Finally, the product was dried at 60 ˚C for overnight.
Preparation of Co3O4/SN-GQDs nanoparticles
First, 0.3g as-prepared Co3O4 was dispersed in 20 ml prepared SN-GQDs solution under sonication for 45 min. Then, the mixture was stirred at ambient condition for 24 hours. The prepared nanocomposites was collected via centrifuge (12000 rpm) and dried at 50 ˚C for overnight.
Characterization
Using Ni-filtered Cu K radiation, the XRD patterns were reported using a Rigaku D-max C III X-ray diffractometer (Rigaku Corporation, Shibuya-ku, Japan) (λ = 1.5418 Å). SEM images were obtained using an LEO instrument model 1455VP. Transmission electron microscope (TEM) images were obtained on a Philips EM208S transmission electron microscope with an accelerating voltage of 100 kV. UV–vis diffuse reflectance spectroscopy analysis (UV–vis) was carried out using Shimadzu UV-vis scanning spectrometer. Fourier transform infrared (FT-IR) spectra were recorded using a Nicolet 6700 FT-IR spectrophotometer at room temperature.
Photocatalytic test
The photocatalytic efficiency of Co3O4 nanoparticles and Co3O4/SN-GQDs nanocomposites were investigated by degrading methylene blue and methyl orange under visible light irradiation. Until photodegradation, Co3O4 nanoparticles and Co3O4/SN-GQDs nanocomposites (0.01g) and methylene blue and methyl orange solution (10 ppm) were stirred for 30 minutes in the dark to achieve adsorption-desorption equilibrium. At regular intervals, the suspension (2 mL) was removed from the system and isolated. The dye concentration was determined with aid of a UV-vis spectrophotometer.
RESULTS AND DISCUSSION
XRD analysis was utilized for the characterization of crystallinity. Fig. 1 displays XRD analysis of prepared Co3O4 nanoparticles, SN-GQDs, and Co3O4/SN-GQDs nanocomposites. According to the data obtained from the Xpert high score software, the prepared sample has an XRD pattern with JCPDS No.80-0075, space group: P63mc, confirming the successful synthesis of cubic phase Co3O4 nanoparticles. The XRD results were also confirmed the formation of Co3O4 without impurity. The crystalline size was calculated 27 nm via Scherrer equation [26]:
Dc=Kλ/βCosθ (1)
where β is the width of the observed diffraction peak at its half maximum intensity (FWHM), K is the shape factor, which takes a value of about 0.9, and λ is the X-ray wavelength (CuKα radiation, equals to 0.154 nm). Fig. 1b shows the XRD pattern of prepared SN-GQDs. The broad peak at 2θ=24˚ is attributed to the graphitic structure of SN-GQDs. The greater d-spacing value of the SN-GQDs suggests that prepared SN-GQDs still contain oxygen-containing functional groups. This may be linked to GQDs’ size and edge effects. The nanoscale size of the GQDs with just a few layers of graphene sheets is due to the broad diffraction peak. Fig. 3b presents the XRD pattern of Co3O4/SN-GQDs nanocomposites. The compassion of XRD results confirmed the formation of Co3O4/SN-GQDs nanocomposites with any impurity.
Fig. 2 shows The FT-IR spectra of prepared Co3O4 nanoparticles, SN-GQDs, and Co3O4/SN-GQDs nanocomposites. The two characteristic absorption peaks at 581 cm-1 and 624 cm-1 are attributed to Co-O bond. The presence of these peaks confirms the bond formation of Co3+-O (581 cm-1) and Co2+-O (624 cm-1). In SN-GQDs, a strong absorption peak at 1756 cm-1is assigned to the surface-adsorbed COOH functional group. Also, the different appeared peaks at 1000-1500 cm-1 are related to C-C and C-O stretching mode. The FTIR spectra of Co3O4/SN-GQDs nanocomposites also confirm the linking of SN-GQDs to Co3O4 nanoparticles.
Scanning electron microscope (SEM) was applied to investigate the shape, size, and texture of prepared products. For better investigation, the SEM image is presented in two magnifications for each sample (Fig. 3). Fig. 3a and Fig. 3b which is related to SEM images of prepared Co3O4 nanoparticles confirms homogenous nanoparticles with an average 95 nm. For Co3O4/SN-GQDs nanocomposites (Fig. 3c, and Fig. 3d), it is clear that small size SN-GQDs are formed with greater Co3O4 nanoparticles. Transmission electron microscopy (TEM) was applied for in-depth morphological examination of Co3O4 nanoparticles, and Co3O4/SN-GQDs nanocomposites. Fig. 4a, and Fig. 4b show TEM images of Co3O4/SN-GQDs. The obtained results from TEM images is in good agreement with SEM images. As well as shown, the small size SN-GQDs are formed beside Co3O4 nanoparticles. It can be concluded from SEM and TEM images that homogenous Co3O4 nanoparticles and Co3O4/SN-GQDs nanocomposites are formed with nanoscale shape and size.
The UV-Vis diffuse reflectance spectroscopy was applied for the investigation of optical properties of products. Fig. 5a shows two absorption bands in the 423 nm and 586 nm which is due to O2-- Co2+ and O2--Co2+, respectively. Via introducing SN-GQDs it is clear that absorption band is shifted to higher wavelength (visible region) (Fig. 5b). This blue shift lead to application of prepared nanocomposites in photocatalytic process.
Organic pollutants are one of the most problematic concerns. The photocatalytic removal of these contaminants has been found more attention in the recent decade. Fig. 6 and Fig. 7 show the photocatalytic performance of prepared Co3O4 nanoparticles, and Co3O4/SN-GQDs nanocomposites for degradation of methylene blue and methyl orange under visible light respectively. The photocatalytic efficiency was calculated via:
Photocatalytic efiiciency (%) = (C0-Ct/ C0) ×100 (2)
Where C0 (mgL−1) is the initial concentration of methylene blue in solution, and Ct (mgL−1) is the concentration of methylene blue and methyl orange at any irradiation time t (min). It is found that 63% of methylene blue was degraded after 70 minutes via using Co3O4 nanoparticles. The photocatalytic efficiency was raised to 88% after 70 minutes via Co3O4/SN-GQDs nanocomposites. For methyl orange, the photocatalytic efficiency was measured 81% and 56% for Co3O4 and Co3O4/SN-GQDs respectively. The better photocatalytic performance of Co3O4/SN-GQDs may be related to the better charge-separation process in Co3O4/SN-GQDs nanocomposites. UV-Vis analysis revealed that charge transfer from Co3O4 to SN-GQDs and prevents charge recombination in Co3O4. This led to the formation of OH radicals on the surface of Co3O4/SN-GQDs nanocomposites and facilitates the photocatalytic process.
CONCLUSION
In conclusion, Co3O4 nanoparticles, and SN-QDs were prepared via the facile hydrothermal method. Then, Co3O4/SN-GQDs nanocomposites were prepared via the ultrasonic-assisted method. The prepared nanocomposites were characterized via XRD, FTIR, SEM, TEM, and UV-Vis analysis comprehensively. The UV-Vis analysis of samples led to the application of prepared nanomaterials as photocatalysts for the degradation of organic pollutants. The prepared Co3O4 nanoparticles and Co3O4/SN-GQDs nanocomposites were applied for the photodegradation of methylene blue and methyl orange under visible light. The results revealed that Co3O4 nanoparticles can degrade 64% and 56% of methylene blue and methyl orange after 70 minutes under visible light respectively. The photocatalytic efficiency was raised to 88% and 81% for Co3O4/SN-GQDs nanocomposites case against methylene blue and methyl orange respectively. This improvement can be attributed to a better charge-separation process in Co3O4/SN-GQDs nanocomposites.
CONFLICT OF INTEREST
The authors declare that there is no conflict of interests regarding the publication of this manuscript.