Facile Synthesis of Bi₂MoO₆ Microspheres Decorated by CdS Nanoparticles with Efficient Photocatalytic Removal of Levfloxacin Antibiotic

Abstract

Developing high-efficiency and stable visible-light-driven (VLD) photocatalysts for removal of toxic antibiotics is still a huge challenge at present. Herein, a novel CdS/Bi₂MoO₆ heterojunction with CdS nanoparticles decorated Bi₂MoO₆ microspheres has been obtained by a simple solvothermal-precipitation-calcination method. 1.0CdS/Bi₂MoO₆ has stronger light absorption ability and highest photocatalytic activity with levofloxacin (LEV) degradation efficiency improving 6.2 or 12.6 times compared to pristine CdS or Bi₂MoO₆. CdS/Bi₂MoO₆ is very stable during cycling tests, and no appreciable activity decline and microstructural changes are observed. Results signify that the introduction of CdS could enhance the light absorption ability and dramatically boost the separation of charge carriers, leading to the excellent photocatalytic performance of the heterojunction. This work demonstrates that flower-like CdS/ Bi₂MoO₆ is an excellent photocatalyst for the efficient removal of the LEV antibiotic.

1. Introduction

Antibiotics accumulated in water have posed a great threat to the environmental safety and human health. In particular, levofloxacin (LEV), as a typical fluoroquinolone antibiotic, has been widely used to treat human and animal infections. As a result, LEV was excessively accumulated in aquatic environments, causing serious health-risk issues by inducing genetic exchange and the bacterial drug resistance [1,2]. Conventional technologies for the removal of antibiotics in aquatic systems have been restricted due to low efficiency, high cost and/or sophisticated instrumentation. In recent years, the semiconductor-based photocatalysis as a green oxidation technology, has made significant developments for treating water pollutions [3,4,5,6,7,8,9,10]. Bismuth (III)-based semiconductors (e.g., BiOX (X = Cl, Br, I) [11,12,13], Bi₂MoO₆ [14,15,16,17], and Bi₂WO₆ [18]) have been emerging as kinds of high-efficiency photocatalysts. Among them, Bi₂MoO₆ as a good visible-light-driven (VLD) photocatalyst, has been one of the focal research points in the area of photocatalysis. Unlike the popular TiO₂, which only can respond to the ultraviolet light, Bi₂MoO₆ (Eg ≈ 2.5–2.8 eV) is active in the visible-light region. However, Bi₂MoO₆ still suffers from the narrow range of sunlight response and fast electron-hole recombination [15,16,17,19]. Intriguingly, the fabrication of semiconductor heterojunctions is a crucial way to obtain superior photocatalysts [20]. Thus, a multiple of Bi₂MoO₆-based heterojunctions have been fabricated to ameliorate the photocatalytic activity for the removal of pollutants, such as BN/Bi₂MoO₆ [21], Bi/Bi₂MoO₆ [22], C₃N₄/Bi₂MoO₆ [23,24], TiO₂/Bi₂MoO₆ [25], etc. [26,27,28,29,30,31]. Our group has also developed some Bi₂MoO₆-based heterojunction photocatalysts with excellent photocatalytic properties [32,33,34,35,36]. However, the majority of them were employed to degrade traditional dyes to evaluate their activity, their application in decomposing colorless and refractory pollutants were underdeveloped.

CdS is known as a promising VLD photocatalyst in virtue of its favorable visible-light-response, and chemical stability [37,38,39,40]. Due to the well-matched band structures of CdS and Bi₂MoO₆ [31], it is anticipated the rationally designed CdS/Bi₂MoO₆ can be endowed with superior photocatalytic activity for the removal of LEV antibiotic. However, reports on photocatalytic degradation of LEV antibiotic using flower-like CdS/Bi₂MoO₆ have not been indicated.

Inspired by the above aspects, we designed a flower-like CdS/Bi₂MoO₆ for the removal of the LEV antibiotic. A facile solvothermal-precipitation-calcination method was employed to construct hierarchical CdS/Bi₂MoO₆ heterojunctions with tightly interfacial contact. 1.0CdS/Bi₂MoO₆ possesses the highest activity towards the removal of LEV antibiotic. The plausible photocatalytic mechanism for the degradation of LEV antibiotic over CdS/Bi₂MoO₆ was also illustrated.

2. Results

2.1. Preparation and Characterization

CdS/Bi₂MoO₆ heterojunctions with CdS/Bi₂MoO₆ molar ratios of 0.5:1, 0.75:1, 1.0:1, and 1.5:1 were fabricated and denoted as 0.5CdS/Bi₂MoO₆, 0.75CdS/Bi₂MoO₆, 1.0CdS/Bi₂MoO₆, and 1.5CdS/Bi₂MoO₆, respectively. The crystalline phases of Bi₂MoO₆, CdS, and the optimal sample (1.0CdS/Bi₂MoO₆) were examined by XRD technique (Figure 1). All the diffraction peaks for Bi₂MoO₆ and CdS correspond to crystal planes of orthorhombic (JCPDS 76-2388) [25,33] and (JCPDS 75-1545) [31], respectively. As for 1.0 CdS/Bi₂MoO₆, both the diffraction peaks belonging to Bi₂MoO₆ and CdS were detected in the XRD pattern, verifying the fabrication of CdS/Bi₂MoO₆.

The morphology of Bi₂MoO₆ and 1.0CdS/Bi₂MoO₆ was characterized by SEM and TEM analysis. As shown in Figure S1, pristine Bi₂MoO₆ has the shape of a microsphere with a smooth surface, in accordance with the morphology of the reported Bi₂MoO₆ [25]. In comparison with Bi₂MoO₆, the surface of 1.0CdS/Bi₂MoO₆ became rough due to the coating of CdS nanoparticles (size: 5–25 nm) (Figure 2a,b), such a hetero-structure favors the separation of charges. In addition, the EDX spectrum shows the co-existence of Cd, S, Bi, Mo and O elements in 1.0CdS/Bi₂MoO₆ (Figure 2c). The detailed microstructure of 1.0CdS/Bi₂MoO₆ revealed by TEM analysis (Figure 2d) shows that the surfaces of Bi₂MoO₆ nanoplates (size: 200 nm) are deposited by numerous of CdS nanoparticles (size: 5–25 nm). The above characterizations further verify the formation of CdS/Bi₂MoO₆.

The UV-Vis absorption spectra of Bi₂MoO₆, CdS, and 1.0CdS/Bi₂MoO₆ are illustrated in Figure 3. Pure Bi₂MoO₆ and CdS exhibit good absorption in the visible light region, consistent with the previous reports [18,37,40]. Notably, 1.0CdS/Bi₂MoO₆ presents better optical absorption than Bi₂MoO₆, indicating that 1.0CdS/Bi₂MoO₆ possesses a better ability to harvest sunlight.

2.2. Photocatalytic Performance

A typical fluoroquinolone antibiotic LEV is a kind of persistent organic pollutants (POPS) due to its water solubility and chemical stability. Photocatalysis is a promising technique for the removal of LEV antibiotic. For example, Kaur et al. fabricated Bi₂WO₆ nanocuboid (0.75 g/L) for almost 80% degradation of LEV (10 mg/L) within 150 min under visible light irradiation [41]. In this work, the photocatalytic activity of CdS/Bi₂MoO₆ heterojunctions was also evaluated by degrading LEV as a representative toxic antibiotic under visible light (Figure 4). No LEV degradation was detected in the blank test (without catalysts). Pure CdS or Bi₂MoO₆ shows very limited photocatalytic activity, as only 20.6% or 10.8% of LEV was decomposed within 60 min of reaction, owing to the fast recombination of electron-hole pairs. Encouragingly, with the introduction of CdS into the composites, all of the CdS/Bi₂MoO₆ heterojunctions show much enhanced photocatalytic activity compared to pristine CdS and Bi₂MoO₆. Notably, 1.0 CdS/Bi₂MoO₆ obtains the highest activity with 80.4% of LEV degradation within 60 min, much higher than CdS (20.6%), Bi₂MoO₆ (10.9%), or the mechanical mixture (25.8%), verifying the existence of synergistic interaction between CdS and Bi₂MoO₆. Since the introduction of CdS nanoparticles on Bi₂MoO₆ microspheres, the intimately contacted interfacial surface is formed for effective separation of charge carriers. However, with the excessive deposition of CdS (1.5CdS/Bi₂MoO₆), the agglomeration of CdS undermines the synergistic effect, and thus suppresses the interfacial charge transfer, resulting in the decrease of the photocatalytic activity.

To make a quantitative comparison, the LEV degradation data were fitted with the pseudo-first-order model (Figure 4b), −ln(C/C₀) = kt. Clearly, 1.0CdS/Bi₂MoO₆ has the largest rate constant of 0.0259 min⁻¹, which is approximately 6.2, 12.6 or 4.5 times higher than pristine CdS (0.0036 min⁻¹), Bi₂MoO₆ (0.0019 min⁻¹), and the mixture (0.0047 min⁻¹).

The mineralization of organic contaminants is pivotal in the wastewater treatment. To assess the mineralization of LEV, TOC values were recorded during the degradation of LEV (40 mg L⁻¹, 200 mL) by 1.0CdS/Bi₂MoO₆ (200 mg). As depicted in Figure 5, 90.1% of TOC was removed after 2.5 h of reaction. These results indicate that 1.0CdS/Bi₂MoO₆ could effectively decompose and mineralize the LEV antibiotic.

The reusability of a photocatalyst is an important factor for the practical treatment of wastewater. Therefore, the cycling runs in LEV degradation over 1.0CdS/Bi₂MoO₆ were executed. Inspiringly, 1.0CdS/Bi₂MoO₆ retained its initial photocatalytic activity after six successive runs (Figure 6a). Moreover, compared to the crystal phase of the fresh 1.0CdS/Bi₂MoO₆, no obvious phase changes (Figure 6b) of the used one was detected, illustrating that 1.0CdS/Bi₂MoO₆ has superior stability and reusability.

2.3. Photocatalytic Reaction Mechanism

A batch of experiments was conducted to analyze the photocatalytic reaction mechanism accounting for the degradation of the LEV antibiotic under visible light through adding various scavengers (Figure 7). The LEV degradation rate showed no obvious decline when IPA (scavenger of •OH) was introduced, indicating that •OH did not play a pivotal role. By contrast, the LEV degradation rate was substantially suppressed by BQ (quencher of O₂^•−) or AO (quencher of h⁺), reflecting that O₂^•− and h⁺ could be the dominant active species responsible for the LEV degradation over 1.0CdS/Bi₂MoO₆.

The bandgap (E_g) of Bi₂MoO₆ and CdS were calculated by the equation: (αhν) = A(hν-E_g)^n/2. As presented in Figure S2, the E_g of Bi₂MoO₆ and CdS are about 2.66 eV and 2.24 eV, consistent with the reference [32,40,42]. The valence band (VB) and conduction band (CB) of Bi₂MoO₆ and CdS can be obtained by the following equation: E_VB = X − E₀ + 0.5 E_g (1), E_CB = E_VB − E_g (2). Thereby, the E_VB and E_CB of Bi₂MoO₆ were −0.32 and 2.34 eV [36], while those of CdS were −0.56 and 1.68 eV [40]. Apparently, a staggered type II band structure can be constructed in CdS /Bi₂MoO₆, beneficial to retarding the recombination of charge carriers.

Since the separation and transport rate of electron-hole pairs of a semiconductor are closely related to the fluorescence emission [29,43,44,45], the photoluminescence (PL) technique was applied to study the transport behaviors of charge carriers in Bi₂MoO₆ and 1.0CdS/Bi₂MoO₆ (Figure S3). Through comparing the PL emission spectra of Bi₂MoO₆ and 1.0CdS/Bi₂MoO₆ (Figure S3), it is found that 1.0CdS/Bi₂MoO₆ exhibits much lower fluorescence intensity compared to that of pure Bi₂MoO₆, indicating that the nano-junction between Bi₂MoO₆ and CdS greatly promotes the separation of electron-hole pairs.

On the basis of above experimental results, the interfacial charge transfer behavior of CdS/Bi₂MoO₆ is illustrated in Figure 8. Under visible-light illumination, electron-hole pairs can be produced in both CdS and Bi₂MoO₆. The photo-excited e⁻ in the CB of CdS may rapidly migrate to that of Bi₂MoO₆, while the photo-excited holes in the VB of Bi₂MoO₆ can preferably drift to that of CdS. Such an interfacial charge movement can effectively retard the electron-hole recombination, accounting for the amelioration of photocatalytic performance of CdS/Bi₂MoO₆. The CB potential of CdS (−0.56 eV) and is Bi₂MoO₆ (−0.32 eV) are more negative than E (O₂/O₂^•−) (+0.13 eV) [46], thus the e^– in the CB of CdS and Bi₂MoO₆ can react with O₂ to generate active O₂^•−, further decomposing LEV antibiotic. On the other hand, the holes collected in the VB of CdS and Bi₂MoO₆ can directly decompose the LEV antibiotic due to their strong oxidation ability.

3. Materials and Methods

3.1. Chemicals

All reagents were purchased from Shanghai Chemical Reagent factory (China) and used directly.

3.2. Chemicals Synthesis of Catalysts

Synthesis ofBi₂MoO₆: Typically, 1 mmol Bi(NO₃)₃·5H₂O and 0.5 mmol Na₂MoO₄·2H₂O were added into 50 mL of ethylene glycol, and the mixture turned into clear solution with the assistance of ultrasonication for 0.5 h. After that, 30 mL of ethanol was poured into the above solution and kept stirring for 0.5 h. Subsequently, the resulting solution transferred into an autoclave with the volume of 100 mL and reacted at 160 °C for 20 h in an oven.

Synthesis of CdS/Bi₂MoO₆: 0.5 mmol Bi₂MoO₆ was suspended into 50 mL of deionized water. Then, 1mmol CdCl₂·2.5H₂O was dissolved in the above suspension under vigorously stirring. After that, 40 mL of Na₂S (1 mmol) aqueous solution was added into the above system dropwise under magnetically stirring for 2 h. The precipitation labeled as 1.0 CdS/Bi₂MoO₆ was washed, dried and then calcined at 200 °C for 2 h in N₂ atmosphere to obtain the catalysts. Through adjusting the amount of precursor of CdS, the samples with CdS/Bi₂MoO₆ molar ratios of 0.5:1, 0.75:1, and 1.5:1 are labeled as 0.5CdS/Bi₂MoO₆, 0.75CdS/Bi₂MoO₆, and 1.5CdS/Bi₂MoO₆, respectively. The CdS sample was also prepared by the same procedure in the absence of Bi₂MoO₆.

3.3. Characterization

The phases of products were characterized via X-ray diffractometer (XRD, Bruker D8 ADVANCE, Karlsruhe, Germany) equipped with mono-chromatized Cu Kα radiation. UV‒Vis diffuse reflectance spectra (DRS) of products were collected using Shimadzu UV‒2600 spectrophotometer with BaSO4 as the reference standard. Scanning electron microscopy (SEM, Hitachi S-4800, Tokyo, Japan) and transmission electron microscopy (TEM, JEM-2100 JEOL, Tokyo, Japan) were employed to characterize the microstructures of the samples. The corresponding elemental components were analyzed by energy-dispersive X-ray spectroscopy (EDS, Bruker Quantax 400, Berlin, Germany). Photoluminescence (PL) spectra were conducted using Hitachi RF-6000 spectrophotofluorometer with the excitation wavelength of 300 nm.

3.4. Photocatalytic Performance Tests

The photocatalytic property of CdS/Bi₂MoO₆ was assessed by degradation of LEV antibiotic under visible-light illumination, and the light source is provided by a 300 W xenon lamp with a light filter λ > 400 nm. 50 mg of catalyst was scattered in LEV (100 mL, 20 mg L⁻¹) solution. The suspension was stirred in the dark for 0.5 h. Then the reaction was initiated when the lamp switches on. During the irradiation, 1.5 mL of suspension was sampled in 10 min. The LEV concentrations were analyzed by using UV-2600 spectrophotometer. Total organic carbon (TOC) of the LEV solutions during reaction was determined by using a Shimadzu TOC analyzer.

4. Conclusions

In summary, CdS nanoparticles interspersed-Bi₂MoO₆ heterojunction photocatalytst was fabricated by a facile solvothermal-precipitation-calcination method. Due to the introduction of CdS, the photo-absorption of CdS/Bi₂MoO₆ and the interfacial charge separation were remarkably enhanced and promoted. By virtue of these benefits, in comparison with bare CdS and Bi₂MoO₆, 1.0CdS/Bi₂MoO₆ presents profoundly enhanced visible-light photocatalytic activity for the removal of the LEV antibiotic. Moreover, 1.0CdS/Bi₂MoO₆ also possesses good stability and can effectively mineralize the LEV antibiotic. This work offers new insight into the design of high-performance Bi-based heterojunction photocatalysts for antibiotic wastewater treatment.