English

• Since last decades, pharmaceuticals and personal care products (PPCPs) including antibiotics, antidepressants, anti-inflammatories, etc., have been the emerging concerns in the environmental contaminants and drawn the researchers' focus due to the widely and frequently detection all around the world [1-6]. As the largest consumer and producer of PPCPs in the world, China has expended more than 2.5 × 10⁷ kg antibiotics per year [7, 8]. In addition, some researchers have investigated the detected PPCPs in Liaohe, Haihe, Yangtze, Pearl, Yellow, Songhuajiang Rivers watershed and the Liaodong Bay, Bohai Bay, Victoria Harbor etc. [1]. Among 65 antibiotics, three sulfonamides, i.e., sulfamethazine (SMT), sulfamethoxazole (SMX) sulfadiazine (SD), are vastly detected throughout China [1, 9]. Especially SMT was most detected in surface waters of China [1, 10]. Although the detection concentration of SMT in water matrix is relatively low, it still shows high potential toxicity risks to ecosystem [2, 11, 12]. Furthermore, the conventional treatment technologies for drinking water, such as filtration, coagulation, and sedimentation, are not efficient to remove SMT [13]. In addition, some advanced oxidation technologies, i.e., photocatalysis [2, 14, 15], electro-Fenton [16, 17], and Fenton-like [18], have been used to degrade SMT in water. Therefore, treatment for wastewater containing PPCPs, especially improving the solar light response of photocatalysts, is urgent and prior demand.

  Graphitic carbon nitride (g-C₃N₄) as a metal-free and two-dimensional layered structure, is an excellent catalyst with relative narrow bandgap of 2.7 eV and good visible light response [19, 20], thus has drawn extensive concerns for environmental applications such as decontamination and disinfection [21]. In addition, some synthesis methods for g-C₃N₄ have been reported [19, 22]. Moreover, the band structure of g-C₃N₄ can be tuned throughout the facial post-calcination method [22, 23], which is not involving with foreign elements and other semiconductors. Some approaches, such as doping [24], heterostructure design [2, 25], and surface modification [26, 27], have been applied to improve the light absorption on visible light region and photocatalytic activity of catalysts. However, some defects caused by these foreign semiconductors or elements were ignored. In addition, for pristine g-C₃N₄, the direct tune of band structure can control the position of conduction band (CB) and valence band (VB) [22], which provides a simple approach to regulate the charge carrier lifetime and then facilitate the utilization efficiency of solar light.

  Moreover, the photocatalytic degradation mechanisms of SMT were accurately and deeply evaluated by theoretical calculations, in specific Fukui index based on density functional theory (DFT). In recent years, our group has made lots of efforts on theoretical calculation, such as evaluation on reactive sites of organic pollutants [2, 15, 25, 28-30], calculation on binding energy [31, 32], transition state (TS) and potential energy surface (PES) [33, 34], prediction on electrostatic potential [35].

  In this work, the overall goal was to investigate the effects of polymerization atmosphere and synthesis condition for the photocatalytic activity of graphitic carbon nitride to degrade sulfamethazine. The detailed objectives were to: 1) Investigate the polymerization method to prepare the g-C₃N₄ under different atmosphere and conditions; 2) evaluate the photocatalytic degradation of SMT by various catalysts; 3) elucidate the mechanism of photocatalytic degradation of SMT and radical attacking via the combination method of the identification on degradation intermediates and analysis by theoretical chemistry; and 4) reveal the underlying mechanism of enhanced photocatalytic activity via material characterizations.

  All chemicals were of analytical grade or higher in this work and described in Text S1 (Supporting information).

  The photocatalysts based on graphitic carbon nitride (g-C₃N₄) derived from melamine were obtained by one-step modified polymerization method in accord with the literature [2, 22]. In brief, 5 g of the melamine was directly put in a crucible, and heated in a tube furnace (Thermo Scientific, USA) to 550 ℃ at a rate of 15 ℃/min under different calcination atmosphere and conditions (open or semi-closed), i.e., static air atmosphere with semi-closed crucible for 3.5 h, air flow atmosphere with open crucible for 3.5 h, argon flow atmosphere with open crucible for 3.5 h, argon flow atmosphere with semi-closed crucible for 2 h following by air flow atmosphere for 1.5 h. Then the final photocatalysts were ground into powder and labeled as pristine g-C₃N₄, g-C₃N₄-open Air, g-C₃N₄-open Ar, and g-C₃N₄-Ar/Air.

  Photocatalytic performances for various materials were investigated via sulfamethazine (SMT) degradation kinetic testes under simulated solar light. In the typical photocatalytic batch reaction, the initial SMT concentration (5 mg/L) and material dosage (0.2 g/L) were fixed in the quartz reactor (reaction volume 250 mL) with cooling system, then solution pH was adjusted to 7.0 ± 0.2 by diluted HClO₄ and NaOH (0.1 mol/L). After 2 h dark adsorption-desorption reaction (300 rpm), the photocatalytic reaction was initiated by turn-on the pre-heated light source, i.e., simulated solar-light simulator system (PLS-SXE300D, Beijing Perfectlight Technology Co., Ltd.) with 300 W Xe lamp providing the 100 ± 0.5 mW/cm² light irradiation (AM 1.5G mode) as shown in Fig. S1 (Supporting information). At pre-determined intervals, the collected samples (each 1 mL) were straightway filtered via a nylon membrane (0.22 µm). Then the concentration of SMT and degradation intermediates in the filtrate was analyzed by high-performance liquid chromatography (HPLC) system (Agilent 1260 Infinity, USA) and ultra-high-performance liquid chromatography-mass spectroscopy system (UHPLC/MS/MS, Thermo scientific, USA), respectively. The analytical details are described in the Text S2 (Supporting information). Control tests, i.e., estimated degradation of SMT by simulated solar light (direct photolysis), were carried out without any catalysts but under otherwise identical conditions.

  To identify the reactive oxygen species (ROS) during the photocatalytic reaction in this work, the generation of ROS was trapped using 5, 5-dimethyl-1-pyrroline-N-oxide (DMPO) as spin-trapping agent, then observed the direct signals on a Bruker EMX/plus X-band (9.5 GHz) Electron Spin Resonance (ESR) spectrometer (Bruker, Billerica, MA) (details in Text S2).

  The materials were characterized by transmission electron microscopy (TEM), X-ray diffraction (XRD), and X-ray photoelectron spectroscopy (XPS). Meanwhile, the band structures of the photocatalysts were analyzed by UV-visible absorption diffuse reflectance spectra (UV-vis DRS) and XPS-valence band (XPS-VB) (Text S3 in Supporting information).

  To evaluate the reactive sites of SMT attacked by ROS, the theoretical calculation, i.e., Fukui index derived from density functional theory (DFT) [15, 25, 29, 30], was used to explain the insights of photocatalytic reaction on Gaussian 16 C.01 software [36] (details in Text S4 in Supporting information). Details on SMT optimized geometry and energy were given in Text S5 (Supporting information).

  Fig. 1a presents the photocatalytic degradation of SMT by various catalysts synthesized by different calcination atmosphere and conditions, i.e., pristine g-C₃N₄, g-C₃N₄-open Air, g-C₃N₄-open Ar, and g-C₃N₄-Ar/Air. Fig. 1b shows the linear fitting to SMT degradation in the photocatalytic system with various catalysts, and Table S1 (Supporting information) lists the fitted parameters. The pseudo-first order kinetic model is applied to interpret the kinetic data [37-39], [40]:

  (1)

  Figure 1

  

  Figure 1.  Photocatalytic degradation of SMT by various catalysts synthesized by different calcination atmosphere and conditions (a) and linear fitting for corresponding kinetic data (b). Initial SMT = 5 mg/L, material dosage = 0.2 g/L, temperature = 25 ± 2 ℃, initial pH: 7.0 ± 0.2, final pH: 7.0 ± 0.5.

  DownLoad: Full-Size Img PowerPoint

  where C₀ and C_t are the SMT concentrations (mg/L) at time 0 and t (h) in aqueous phase, respectively; and k₁ is the first-order rate constant (h⁻¹).

  It is obvious that SMT is hard to be degraded by simulated solar light (< 0.1%) (Fig. 1a), i.e., negligible direct photolysis. In addition, the adsorption of SMT by all catalysts was negligible (< 3%), which mainly can be attributed to the electrostatic repulsion between negative charged catalysts surface, for example, pH_PZC (g-C₃N₄) 5.1 [2] and the SMT species are the form of SMT⁻ and zwitterionic species of SMT^± (Fig. S2 in Supporting information) at pH 7.0, and the lack of the π-π interaction, which is confirmed by other reports [2]. In addition, after light on, the SMT was significantly degraded in the presence of various catalysts, i.e., 1.5 h SMT degradation reached 53.8% for pristine g-C₃N₄ (k₁ = 0.553 h⁻¹), 23.5% for g-C₃N₄-open Air (k₁ = 0.211 h⁻¹), 34.3% for g-C₃N₄-open Ar (k₁ = 0.320 h⁻¹), and 99.0% for g-C₃N₄-Ar/Air (k₁ = 2.696 h⁻¹). Compared to pristine g-C₃N₄, the photocatalytic activities of g-C₃N₄-open Air and g-C₃N₄-open Ar were significantly retarded due to the partial formation of g-C₃N₄ and the existence of polymeric intermediates, i.e., melam, melon, or melon sheet, resulted from the insufficient condensation/polymerization from melamine to g-C₃N₄ under open crucible condition [41]. However, the efficient degradation of SMT by g-C₃N₄-Ar/Air (99.0%, k₁ = 2.696 h⁻¹, 4.9 times than pristine g-C₃N₄) was observed within 1.5 h, indicating the successful synthesis of g-C₃N₄-Ar/Air under argon atmosphere with semi-closed crucible for 2 h followed by air atmosphere for 1.5 h, which is consistent with other report [22].

  Fig. 2 shows the SEM and TEM images of pristine g-C₃N₄, and TEM images of g-C₃N₄-Ar/Air. It is obvious that pristine g-C₃N₄, have a stacked-layer structure (Figs. 2a and b). However, the obtained g-C₃N₄-Ar/Air under Ar-Air-atmosphere exhibited the damaged and partial-collapsed structure (Figs. 2b and c), which is contributed by the release of gases, i.e., NO, NO₂, NH₃, N₂/CO, CO₂ [22], during the polymerization/condensation of melamine, indicating the element loss of carbon and nitrogen. In addition, the released gases leading to hot bubbles (Fig. 2d), which is also observed and reported by other researchers [22, 42, 43], will result in the transformation from pristine g-C₃N₄ into g-C₃N₄-Ar/Air nanosheets via oxidative exfoliation process in the following air atmosphere (Figs. 2a-d) [22]. The morphology and structure variation caused by Ar/Air calcination led to the change of interlayer distance of melon sheets and the shift of band structure [22] which is further confirmed by the XRD results, then suggesting the visible-light absorption edge shift and possibly enhanced photocatalytic activity compared to pristine g-C₃N₄.

  Figure 2

  

  Figure 2.  SEM and TEM images of pristine g-C₃N₄ (a, b); TEM images of g-C₃N₄-Ar/Air (c, d).

  DownLoad: Full-Size Img PowerPoint

  Fig. 3 presents XRD patterns of melamine, pristine g-C₃N₄, and g-C₃N₄-Ar/Air. All the distinctive peaks at 13.1°, 14.8°, 17.7°, 21.7°, 22.1°, 26.2°, 28.8° and 29.8° of melamine were disappeared and transferred to the two significant peaks in pristine g-C₃N₄, i.e., 13.0° and 27.5° for the crystalline plane (100) and (002), respectively (JCPDS No. 01-087-1526) [2, 25, 26] via the static air calcination and polymerization. For g-C₃N₄-Ar/Air, two peaks assigned to (100) and (002) became sharper, indicating better crystalline phase. In addition, the peak of (002) in g-C₃N₄-Ar/Air was slightly shifted to 27.7° from original 27.5° in pristine g-C₃N₄, suggesting that the nanosheet-interlayer distance was decreased due to damaged/partial-collapsed structure and slightly denser stacking of pristine g-C₃N₄ through oxidative exfoliation and planarization by air calcination, which is consistent with previous TEM observations (Fig. 2d). Furthermore, the new peaks at 18.2°, 22.1°, 44.6°, and 57.2° appeared, indicating the layer-by-layer splitting and exfoliation of pristine g-C₃N₄. All above morphology, structure, and crystalline phase change resulted in the shift of band structure, therefore achieving the tune of band position, then improving the photocatalytic activity of g-C₃N₄ without any foreign elements or metals or semiconductors.

  Figure 3

  

  Figure 3.  XRD patterns of melamine, pristine g-C₃N₄, and g-C₃N₄-Ar/Air.

  DownLoad: Full-Size Img PowerPoint

  To further identify the bandgap and the position of band structure, i.e., valence band (VB) and conduct band (CB) of g-C₃N₄-Ar/Air, diffuse reflectance UV-visible absorption spectra (UV-vis DRS) and X-ray photoelectron spectroscopy (XPS-VB) were analyzed respectively. In specific, the absorption spectra of different photocatalysts were directly obtained by UV-vis DRS, then the Kubelka-Munk transferred profiles (as shown in Fig. 4a) were calculated by following equation (Eq. 2) [2-2], [44]:

  (2)

  Figure 4

  

  Figure 4.  Band gap (E_g) values calculated from Kubelka-Munk method (a) and XPS-VB (b) of various g-C₃N₄ catalysts; ESR spectra of DMPO-^•OOH (c) and DMPO-^•OH (d) in the presence of g-C₃N₄-Ar/Air under dark and solar light; tune of band structure on g-C₃N₄-Ar/Air (e).

  DownLoad: Full-Size Img PowerPoint

  where α, h, ν, A, E_g are the absorption coefficient, Planck constant, photon frequency, constant, band gap energy, respectively. n = 1 for direct absorption and n = 4 for indirect absorption.

  As shown in Fig. 4a, the band gap energy (E_g) of pristine g-C₃N₄ and g-C₃N₄-Ar/Air was 2.82 and 2.79 eV, indicating the slight red-shift and band shrinking for the modified g-C₃N₄ via the different calcination atmosphere, and resulting in the better photocatalytic activity, which is consistent with previous TEM and XRD observations. However, the E_g values of pristine g-C₃N₄ and g-C₃N₄-Ar/Air are close. Then the detailed band structures of photocatalysts were analyzed.

  In addition, the VB of various catalysts was obtained by XPS-VB, and then the CB was calculated as below (Eq. 3):

  (3)

  According to Fig. 4b, the VB positions of pristine g-C₃N₄ and g-C₃N₄-Ar/Air were 2.38 and 1.98 eV, respectively, then the calculated CB positions of pristine g-C₃N₄ and g-C₃N₄-Ar/Air were −0.44 and −0.81 eV, respectively, indicating the band upshift in g-C₃N₄-Ar/Air, which is benefit to transfer electrons to O₂ forming ^•O₂⁻. In addition, for g-C₃N₄-Ar/Air catalyst under solar light irradiation, the ESR spectra exhibited the existence of DMPO-^•OOH (Fig. 4c) and DMPO-^•OH (Fig. 4d) [22], indicating the generation of ^•OOH, which is derived from the protonation process of superoxide radical (^•O₂⁻), and ^•OH. Therefore, the dominant mechanism for SMT degradation by g-C₃N₄-Ar/Air under simulated solar light in this work is radical attacking by ^•O₂⁻ and ^•OH. The details on the generation mechanism of radicals and the degradation pathway of SMT in the photocatalytic system will be demonstrated in the following section based on intermediates analysis and theoretical calculation.

  Fig. 4e elucidates the enhanced mechanism on photocatalytic activity of g-C₃N₄-Ar/Air. Based on the the Kubelka-Munk transferred profiles (Fig. 4a derived from UV-vis DRS) and XPS-VB (Fig. 4b), the VB positions of pristine g-C₃N₄ (2.38 eV) and g-C₃N₄-Ar/Air (1.98 eV), i.e. h_VB⁺ in both catalysts, were hard to oxidize the H₂O or OH⁻ to generate ^•OH due to less redox potential than H₂O or OH⁻/^•OH (2.72 or 2.40 V vs. NHE), respectively [2, 45, 46]. Moreover, the CB position in g-C₃N₄-Ar/Air was upshifted from −0.44 eV of pristine g-C₃N₄ to −0.81 eV, suggesting the powerful ability on donating the electrons for O₂ to form ^•O₂⁻ (O₂/^•O₂⁻ = −0.33 V vs. NHE) [46, 47]. In addition, the detection of DMPO-^•OOH, which is due to the protonation of ^•O₂⁻ in the aqueous phase, also strongly supported the aformentioned results. However, ^•OH was also detected although h_VB⁺ in g-C₃N₄-Ar/Air cannot directly oxidize the H₂O or OH⁻, which is mainly attributed by the radical chain reactions and transferred from ^•O₂⁻ [48-52]. Then for g-C₃N₄-Ar/Air, the combination of narrower E_g and more negative CB is benefited and favored to generate highly active CB-e⁻, resulting in the enhnanced photocatalytic activity than pristine g-C₃N₄. The dominant mechanism on the generation of radicals in this photocatalytic system can be summarized as follows:

  (4)

  (5)

  (6)

  (7)

  (8)

  Based on DFT, the optimized geometry structure of SMT was presented in Fig. 5a and the optimized cartesian coordinates were listed in Text S5 (Supporting information). Then the Fukui index, f ^– in this study, was used to predict the reactive sites on SMT molecule by electrophilic attack, which was shown in Fig. 5b. Furthermore, superoxide (^•O₂⁻) and hydroxyl (^•OH) radicals are the primary reactive oxygen species (ROS) in this photocatalytic degradation system. Both of these two radicals preferred to attack the electron-rich sites of SMT, thus categorized as electrophilic radicals [2, 28, 34, 53]. In addition, the identified photocatalytic degradation intermediates (IMs) of SMT in this system are presented in Fig. 5c. High f ^– value on SMT molecule suggested that the sites preferred to lose electron then be attacked by ^•O₂⁻ and ^•OH. In specific, the C15 (f ^– = 0.12), N7 (f ^– = 0.114), and N9 (f ^– = 0.096) are ranked in the first-stage reactive sites of SMT. Then the following stages are the reactive site on benzene ring, i.e., C4 (f ^– = 0.064) and C6 (f ^– = 0.06). Considering the detailed reaction conditions, i.e., at neutral pH, the N–S bond cleavage will occur due to radical attacking on the high f ^– value of N9 in the first-stage reactive site of SMT, resulting in the formed IMs of B and C, which is confirmed by UHPLC/MS/MS detection (Fig. 5c). Meanwhile, the IM A was generated due to ^•OH addition, which is consistent with the prediction of benzene ring in the second-stage. Then, IM D was formed throughout the further radical attacking on IMs A or B. After further deep oxidation by ROS, low molecular weight compounds were produced then transformed into the final mineralization products (CO₂ and H₂O).

  Figure 5

  

  Figure 5.  Chemical structure of SMT (a), natural population analysis (NPA) charges and Fukui index (f⁻) of SMT (b) and degradation pathway of SMT in the photocatalysis system (c).

  DownLoad: Full-Size Img PowerPoint

  In conclusion, we demonstrated the tuning process of band structure for graphitic carbon nitride through the control of atmospheric condition without involving any foreign elements or metals or semiconductors, which can efficiently photocatalytic degrade SMT under simulated solar light, i.e., 99.0% removal of SMT by g-C₃N₄-Ar/Air with rate constant k₁ = 2.696 h⁻¹ within 1.5 h (4.9 times than pristine g-C₃N₄). TEM and XRD confirmed the damaged/partial-collapsed structure and decreased nanosheet-interlayer distance due to the denser stacking of pristine g-C₃N₄ through oxidative exfoliation and planarization by air calcination. Then the change of morphology and structure will result in the shift of band structure, i.e., the bandgap of g-C₃N₄-Ar/Air was shrunk from 2.82 eV (pristine g-C₃N₄) to 2.79 eV, and the CB was upshifted from −0.44 eV (pristine g-C₃N₄) to −0.81 eV, indicating the higher potential power for transferring electrons to oxygen, then achieving the tune of band position and improving the photocatalytic activity. Fukui index (f ^–) based on DFT calculation indicated that the sites of SMT molecule with high value, i.e., N9, C4 and C6, preferred to be attacked by the produced electrophilic radicals (^•O₂⁻ and ^•OH), resulting in the N–S bond cleavage and hydroxyl radical addition. In addition, the prediction of reactive sites on SMT is confirmed by the formation of intermediates via UHPLC/MS/MS analysis. The tuning method for graphitic carbon nitride is a promising procedure for photocatalyst modification, which exhibits great potential in efficient removal of emerging organic contaminants from wastewater.

  Declaration of competing interest

  The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

  Acknowledgments

  This work was partially supported by the National Natural Science Foundation of China (Nos. 21906001, 52100069, 51721006 and 41272375), Beijing Nova Program (No. Z191100001119054), the Fundamental Research Funds for the Central Universities (No. BFUKF202118), and China Postdoctoral Science Foundation (No. 2021M690208).

  Supplementary materials

  Supplementary material associated with this article can be found, in the online version, at doi:10.1016/j.cclet.2021.08.061.

  
  
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  Figure 1  Photocatalytic degradation of SMT by various catalysts synthesized by different calcination atmosphere and conditions (a) and linear fitting for corresponding kinetic data (b). Initial SMT = 5 mg/L, material dosage = 0.2 g/L, temperature = 25 ± 2 ℃, initial pH: 7.0 ± 0.2, final pH: 7.0 ± 0.5.

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  Figure 2  SEM and TEM images of pristine g-C₃N₄ (a, b); TEM images of g-C₃N₄-Ar/Air (c, d).

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  Figure 3  XRD patterns of melamine, pristine g-C₃N₄, and g-C₃N₄-Ar/Air.

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  Figure 4  Band gap (E_g) values calculated from Kubelka-Munk method (a) and XPS-VB (b) of various g-C₃N₄ catalysts; ESR spectra of DMPO-^•OOH (c) and DMPO-^•OH (d) in the presence of g-C₃N₄-Ar/Air under dark and solar light; tune of band structure on g-C₃N₄-Ar/Air (e).

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  Figure 5  Chemical structure of SMT (a), natural population analysis (NPA) charges and Fukui index (f⁻) of SMT (b) and degradation pathway of SMT in the photocatalysis system (c).

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