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. 2023 Jul 21;13(32):22054–22060. doi: 10.1039/d3ra02062b

Synthesis of Sb2S3 nanosphere layer by chemical bath deposition for the photocatalytic degradation of methylene blue dye

Mohammed M Gomaa a,, Mohamed H Sayed a,b, Mahmoud S Abdel-Wahed c, Mostafa Boshta a
PMCID: PMC10359849  PMID: 37483670

Abstract

An antimony tri-sulfide Sb2S3 nanosphere photocatalyst was effectively deposited utilizing sodium thiosulfate and antimony chloride as the starting precursors in a chemical bath deposition process. This approach is appropriate for the large-area depositions of Sb2S3 at low deposition temperatures without the sulfurization process since it is based on the hydrolytic decomposition of starting compounds in aqueous solution. X-ray diffraction patterns and Raman spectroscopy analysis revealed the formation of amorphous Sb2S3 layers. The scanning electron microscopy images revealed that the deposited Sb2S3 has integrated small nanospheres into sub-microspheres with a significant surface area, resulting in increased photocatalytic activity. The optical direct bandgap of the Sb2S3 layer was estimated to be about 2.53 eV, making amorphous Sb2S3 appropriate for the photodegradation of organic pollutants in the presence of solar light. The possibility of using the prepared Sb2S3 layer in the photodegradation of methylene blue aqueous solutions was investigated. The degradation of methylene blue dye was performed to evaluate the photocatalytic property of Sb2S3 under visible light. The amorphous Sb2S3 exhibited photocatalytic activity for the decolorization of methylene blue solution under visible light. The mechanism for the photocatalytic degradation of methylene blue has been proposed. Our results suggest that the amorphous Sb2S3 nanospheres are valuable material for addressing environmental remediation issues.

An antimony tri-sulfide Sb2S3 nanosphere photocatalyst was effectively deposited utilizing sodium thiosulfate and antimony chloride as the starting precursors in a chemical bath deposition process.graphic file with name d3ra02062b-ga.jpg

Introduction

Nanostructured metal sulfides (NMSs) have recently attracted considerable interest in a number of applications owing to their distinct optoelectronic and catalytic properties.1–3 These properties depend greatly on the morphologies and dimensions of the prepared materials,4 making these materials feasibly useful in various applications, such as dye removal from wastewater,5 energy conversion and storage,6 rechargeable lithium-ion batteries,7 hydrogen evolution,8,9 and photocatalysts.10 Metal sulfide nanostructures with controllable nanoshapes, such as particles, wires, sheets, flakes,11 hollow spheres,12 and core–shell structures,13 have been regarded as potential cost-effective, chemically stable, and nontoxic semiconducting materials for catalytic applications.8,14,15

Spherical structures are a type of functional material that has a high surface area and small charge transport lengths.16 Spherical structures are classified as basic or complex based on their structural complexity. Simple spherical formations are one thing, as are solid spheres and single-shelled hollow spheres.17 Because of their customizable physical and chemical properties, spherical structures offer significant structural advantages for electrochemical applications. High complexity hollow spherical micro/nanostructures have drawn significant interest in both theoretical studies and practical applications. Nanostructured spherical materials showed enhanced electrochemical performance and structural stability compared to the other alternative structures.16,18 The variety of the material forms offers more potential for increasing functionality than simple spherical structures, which enhances the photocatalytic performance of the active material.15,16

Metal sulfide materials have received a great deal of attention and study.19–25 Among metal sulfides, antimony sulfides with different phases have received significant attention owing to their unique physical properties, low toxicity, abundance, and environment-friendliness, making them ideal candidates for solar cells and environmental applications.26 Sb2S3 can have either an amorphous phase known as metastibnite or a crystalline phase known as stibnite, depending on the synthesis process. The amorphous Sb2S3 phase has a direct energy gap (Eg) in the range of 1.7–2.8 eV, while the Eg for the crystalline phase ranges between 1.7 and 1.8 eV.27 In terms of application, the photocatalytic performance of antimony compounds in the degradation of organic pollutants is still less efficient compared to other photocatalysts based on noble metals and phosphides.3,28 In this regard, limited work has been devoted to using Sb2S3 as a photocatalytic material in the degradation of organic dyes.29 In addition, amorphous and crystalline Sb2S3 in the powder form have displayed an enhanced photocatalytic degradation of organic dyes with visible light.30,31 To the best of our knowledge, nanosphere Sb2S3 layers have not been investigated before in the photocatalytic degradation of organic dyes. The innovative characteristic quality within the Sb2S3 layers that causes the separation of those materials will secure their multiple usages and consequently reduce the overall treatment cost. Therefore, the creation of a more sufficient synthesis process for the inorganic nanosphere is important. Additionally, amorphous Sb2S3 layers are still quite uncommon and require more investigation.32 Most of the chemical methods are suitable for preparing antimony sulfides in powder form with different phases.9,33 Among these approaches, chemical bath deposition (CBD) is one of the most attractive deposition processes because it is simple, cost-effective, and suitable for depositing a large area of thin films. The demand for an approach to prepare thin films with a high specific area and controlled morphology is still a major challenge, and it will open doors to diverse prospects for environmental application.

Methylene blue is a persistent organic pollutant material that is used in textile manufacturing for dyeing objectives in the modern world. Waste from textile manufacturing deteriorates water resources, and is detrimental to humans and other living organisms because of the potential for eye diseases, kidney diseases, and skin diseases. These types of pollutants cannot be removed by conventional treatment.34 Thus, the development of novel methods is needed to address this concern. One of the main issues in the photocatalyst process is the separation and recovery constraint of the photocatalyst from the effluent after the treatment process. Therefore, this work overcomes this issue through the deposition of Sb2S3 on a glass substrate as thin layers.

A feasible CBD approach was used in this study to effectively produce Sb2S3 nanosphere layers directly without the need for a sulfurization process. The structural, morphological, optical, and catalytic properties of the resulting Sb2S3 layers were investigated. The unique nanosphere shape of the Sb2S3 layers acts as a powerful photocatalyst for the photodegradation of methylene blue dye.

Experimental

Sb2S3 layer deposition

Initially, the chemical bath deposition (CBD) technique was employed to prepare a nanosphere-structured antimony sulfide layer. The used glass substrates were cleaned in an ultrasonic bath with acetone, ethyl alcohol, and distilled water separately for 20 minutes, followed by nitrogen gas drying. As the starting solution, antimony chloride (SbCl3 – Sigma Aldrich) was dissolved in acetone and dropped into 1 M sodium thiosulfate (Na2S2O3·5H2O – Sigma Aldrich) aqueous solution with continuous stirring, producing clear and homogeneous solution. During the synthesis process, the cleaned substrates were vertically dipped in the solution bath at a low deposition temperature and pH of 6. After 10 minutes, the colorless solution was transformed into an orange–yellow solution with the Sb2S3 layer formed on the substrate surface due to the adsorption and nucleation of antimony sulfide on the substrate. To remove the residual precipitation, the deposited layers were washed several times with distilled water. Fig. 1 shows a schematic representation of the chemical bath deposition process of the nanosphere-structured Sb2S3 layer.

Fig. 1. Schematic description of the synthesis of nanosphere Sb2S3 layers.

Fig. 1

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The deposition was performed in a relatively weak acidic solution at pH approximately 3. Hence, the mechanism of the nanosphere-structured as-deposited Sb2S3 layer using thiosulphate solution is based on the hydrolytic decomposition of antimony(iii) thiosulphate complexes of Sb2(S2O3)3 formed in aqueous media as a result of the reaction between SbCl3 and Na2S2O3, as in the following reactions:35,36

2SbCl3 + 3Na2S2O3 → Sb2(S2O3)3 + 6NaCl 1
2Sb3+ + 3S2O32− → Sb2(S2O3)3 2

Thiosulphate ions in acidic media can gradually release S2− ions during hydrolytic decomposition, according to the reactions.

S2O32− + H+ → S + HSO3 3
S + 2e → S2− 4

The released excess S2− ions react with the Sb3+ ions released from the thiosulphate complexes upon hydrolysis, reacting on the glass substrates to form orange-yellow Sb2S3:

2Sb3+ + 3S2− → Sb2S3 5

Characterization of the as-deposited Sb2S3 layer

In this study, Cu Kα radiation at 40 kV and 40 mA was used to conduct X-ray diffraction (XRD) investigations for the structural and phase examination of the Sb2S3 layer. The morphology of the deposited layers was imaged using FEI Quanta 250 FEG scanning electron microscopy (SEM). X-Ray photoelectron spectroscopy (XPS) data were collected using a K-ALPHA (Themo Fisher Scientific, USA) spectrometer to determine the chemical composition and electronic states of the Sb2S3 layer. The Raman study was carried out using a Witec Alpha 300 RA confocal Raman microscope with laser excitation at 532 nm. Optical measurements were performed using a UV/VIS/NIR spectrophotometer (Jasco V770).

Evaluation of the photocatalytic performance of the Sb2S3 layers

The photocatalytic activity of the as-prepared Sb2S3 this film was recognized by methylene blue photodegradation as a model of the refractory organic contaminants. For this goal, the Sb2S3 sample was fixed on a 2 cm-height edge inside a 150 mL beaker by a silicon adhesive. After that, the beaker was filled with 90 mL of 10 mg L−1 methylene blue solution, and stirred by a magnetic stirrer. Then, the beaker was irradiated vertically using a UVACUBE 400 sunlight simulator (Dr Hönle AG UV Technology, Germany). At definite time intervals, online measurement of methylene blue removal was performed by spectrophotometer (Jasco 630). The creation of the redox reactive species by the Sb2S3 thin film slide excited by solar irradiation was studied by 1 mmol ammonium oxalate (AO), para-benzoquinone (p-BQ) and isopropyl alcohol (IPA) as the hole (h+) scavenger agent, the superoxide radical (O2˙) scavenger and as the hydroxyl radical ˙OH scavenger, respectively.

Results and discussion

Structural and elemental composition properties

The XRD and Raman data of the produced Sb2S3 layer are presented in Fig. 2. It is seen that no obvious characteristic peaks were observed in the XRD spectrum of the as-deposited Sb2S3 layer by the CBD method, indicating that the deposited layer has an amorphous phase structure, as shown in Fig. 2(a).

Fig. 2. (a) XRD pattern of Sb2S3 and (b) Raman spectra of Sb2S3 before and after the photocatalytic test.

Fig. 2

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The obtained results are in agreement with the previously reported XRD data for the Sb2S3 deposited by CBD in different media and different starting sulfur precursors,37,38 and the reported amorphous Sb2S3 phase prepared by thermal evaporation technique.39Fig. 2(b) shows the Raman spectrum of Sb2S3 before and after photocatalytic test. The appearance of a broad peak in the range of 250–350 cm−1 and centered at the position 289 cm−1 indicated the existence of Sb2S3 in the amorphous phase, as described in prior studies.40–42 The Raman spectra clearly indicate that no structural changes are observed in the Sb2S3 layers after the test.

This work used X-ray photoelectron spectroscopy (XPS) measurements to investigate the elemental compositions and electronic states of a nanosphere Sb2S3 layer. Fig. 3(a) presents the high-resolution XPS spectrum of Sb 3d for the deposited Sb2S3 layer, which has two main peaks located at 529.93 eV and 539.22 eV. These two peaks were assigned to the spin–orbit splitting of Sb 3d5/2 and Sb 3d3/2, respectively, which was separated by 9.29 eV. The binding energies values and the separation by spin orbit coupling suggest that Sb bound to S remains in the Sb3+ oxidation state, which coincides well with the reported values of Sb3+ in the Sb2S3 lattice. These values are within the range of the binding energy values reported by various research groups for the Sb3+ state in the Sb2S3 material.42–44

Fig. 3. XPS spectra of the core levels for deposited Sb2S3: (a) Sb 3d and (b) S2.

Fig. 3

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In addition, the high-resolution spectrum of the S core level presents two peaks, a main peak located at 162.11 eV and a shoulder peak positioned at 160.98 eV, which correspond to the 2p1/2 and 2p3/2 of S2−, respectively, and separated by 1.13 eV as shown in Fig. 3(b). These values imply the existence of unsaturated sulfur atoms on the Sb–S and S–S bonds in Sb2S3.45,46 XPS analysis confirmed that the deposited sample is the Sb2S3 material. The results of the XRD, Raman and elemental composition and chemical states analysis confirmed that the deposited samples are an amorphous Sb2S3, which is in agreement with the reported studies.47,48

Morphological characterization

The SEM images with different magnifications of the deposited samples on the glass are displayed in Fig. 4. The morphological properties of the deposited Sb2S3 indicate a preference for the eventual integration of small nanospheres into sub-microspheres. It is clear that the nanospheres are randomly distributed and have different sizes. The irregularly stacked and merged small nanospheres resulted in consolidated sub-microspheres ranging in size from 0.25 μm to 0.5 μm. Moreover, as can be seen in the magnified images, the sub-microspheres have a rough surface and have a propensity to develop pores within the spheroidal units (Fig. 4(d)). These sub-microspheres are anticipated to offer more practical anchoring sites and allow for the adsorption of organic dyes, which could enhance the photocatalytic activity.12,49,50

Fig. 4. (a)–(d) SEM images with different magnifications of the Sb2S3 layer.

Fig. 4

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Optical properties

Fig. 5(a) displays the optical transmittance and reflectance spectra of the chemically deposited Sb2S3 layer as a function of wavelength ranging between 250 to 2500 nm. The following formula is utilized to calculate the absorption coefficient (α).

graphic file with name d3ra02062b-t1.jpg 6

where T, R, and t are the transmission, reflectance, and film thickness, respectively. The Tauc equation has been presented as a mathematical equation to demonstrate the relationship between the optical energy gap and the energy of the incident photon.

αhν = A(Eg)n 7

where α is the absorption coefficient, is the photon energy, A is a constant, Eg is the band gap, and n is an index that has values of 1/2, 2, 3/2, and 3, depending on the electronic transition of the deposited material.51 The plot of (αhν)2vs. hν for the directly allowed transition is used to calculate the band gap (Eg) of the Sb2S3 layers by extrapolating the linear portion near the onset of the absorption edge to the energy axis, as shown in Fig. 5b. The estimated value of Eg for the Sb2S3 layer was 2.53 eV, which agrees with the reported values.27,52 A similar range of the Eg value would qualify the benefit of this material in the solar photocatalytic applications.42

Fig. 5. (αhν)2versus photon energy () for the nanosphere Sb2S3 layer.

Fig. 5

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Catalytic properties

The photocatalytic activity of the prepared Sb2S3 thin film was performed with 10 mg L−1 methylene blue as the module organic compound at a pH of 6.5, and 5 cm2 area of the Sb2S3 thin film. The change in relative concentration (C/Co) of methylene blue with time is presented in Fig. 6. In the presence of the prepared Sb2S3 thin film and solar light irradiation, the methylene blue (C/Co) decreased with time. The prepared Sb2S3 thin film was activated by the absorbed solar light, which initiated the photoproduction of e/h+ that was employed in the photodegradation of methylene blue. In contrast, the presence of only solar light irradiation without the prepared Sb2S3 thin film resulted in the insignificant photolysis of methylene blue.

Fig. 6. Photocatalytic activity of the prepared Sb2S3 sample, methylene blue = 10 mg L−1, pH 6.5 and Sb2S3 sample (5 cm2).

Fig. 6

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The produced redox species that was generated after exciting the prepared Sb2S3 layer by solar light was identified by appending 1 mmol of the individual scavenger agents (IPA, AO and p-BQ) with 10 mg L−1 methylene blue and the Sb2S3 sample. Fig. 7 represents the effect of the scavengers on methylene blue removal in the presence of scavengers and without scavengers. The hydroxyl radical (˙OH) is a primary active species, the superoxide radicals (O2˙) is a secondary active species, and the hole (h+) is a third active species. Therefore, the suggested mechanism of the photocatalytic reactions is specified by the subsequent equations:

graphic file with name d3ra02062b-t2.jpg 8
OH + h+ → ˙OH 9
O2 + e → O2˙ 10
Methylene blue + h+ + ˙OH + O2˙ → indermediate → degraded products 11

Fig. 7. Effect of scavengers on the methylene blue removal efficiency.

Fig. 7

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One of the most important factors that influence the practical application of the photocatalysts is the reusability test, which will lead to a cost-effective treatment process. So, the photocatalytic activity of the prepared Sb2S3 layer (5 cm2), pH natural and 10 mg L−1 methylene blue on reuse experiments is offered in Fig. 8. An insignificant decrease in the methylene blue photodegradation removal was observed with up to five runs. This demonstrates that the prepared Sb2S3 layer can maintain its photocatalytic activity and stability for more times in treatment processes, as confirmed by Raman measurements.

Fig. 8. Photocatalytic activity of the Sb2S3 sample (5 cm2), natural pH and 10 mg L−1 methylene blue on reuse experiments.

Fig. 8

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Conclusions

In summary, the antimony tri-sulfide Sb2S3 nanosphere layer was synthesized directly by chemical bath deposition method at low deposition temperature and large scale for efficient photocatalytic application. The deposited layer was characterized by various characterization techniques that demonstrated that Sb2S3 has an amorphous phase structure with good morphological and optical properties. X-ray diffraction and Raman analysis showed the amorphous structure of the Sb2S3 films. Optical analyses revealed that the Sb2S3 layer has an optical energy gap of 2.53 eV, which makes these layers a reliable material for photocatalytic application. The photocatalytic activity of Sb2S3 for degrading methylene blue under visible light was investigated. The degradation rate of the amorphous Sb2S3 layer toward methylene blue is highly efficient. This is due to the broad-spectrum response and the proper valence band position of Sb2S3. This investigation indicates that Sb2S3 is an excellent visible-light responsive photocatalyst for degrading organic pollutants.

Author contributions

Mohammed M. Gomaa: conceptualization, data curation, formal analysis, investigation, methodology, writing – original draft. Mohamed H. Sayed: conceptualization, data curation, formal analysis, investigation, methodology, writing – original draft. Mahmoud S. Abdel-Wahed: conceptualization, methodology, data curation, formal analysis, investigation, writing – original draft. Mostafa Boshta: funding acquisition, project administration, resources, supervision, validation, writing – original draft.

Conflicts of interest

The authors declare no competing interests.

Supplementary Material

Acknowledgments

The authors acknowledge the financial support from the National Research Centre Fund, through in-house project numbers 13020240 and 13040124.

Notes and references

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