Highly Efficient Solar-Light-Active Ag-Decorated g-C3N4 Composite Photocatalysts for the Degradation of Methyl Orange Dye

In this study, we utilized calcination and simple impregnation methods to successfully fabricate bare g-C3N4 (GCN) and x% Ag/g-C3N4 (x% AgGCN) composite photocatalysts with various weight percentages (x = 1, 3, 5, and 7 wt.%). The synthesized bare and composite photocatalysts were analyzed to illustrate their phase formation, functional group, morphology, and optical properties utilizing XRD, FT-IR, UV-Vis DRS, PL, FE-SEM, and the EDS. The photodegradation rate of MO under solar light irradiation was measured, and the 5% AgGCN composite photocatalyst showed higher photocatalytic activity (99%), which is very high compared to other bare and composite photocatalysts. The MO dye degradation rate constant with the 5% AgGCN photocatalyst exhibits 14.83 times better photocatalytic activity compared to the bare GCN catalyst. This photocatalyst showed good efficiency in the degradation of MO dye and demonstrated cycling stability even in the 5th successive photocatalytic reaction cycle. The higher photocatalytic activity of the 5% AgGCN composite catalyst for the degradation of MO dye is due to the interaction of Ag with GCN and the localized surface plasmon resonance (SPR) effect of Ag. The scavenger study results indicate that O2●− radicals play a major role in MO dye degradation. A possible charge-transfer mechanism is proposed to explain the solar-light-driven photocatalyst of GCN.


Introduction
As industrial and agricultural areas were developed, environmental pollution became more serious. Organic pollutants are often discharged into wastewater in the form of dyes. Organic pigments and dyes used in industries such as leather, textiles, paper, cosmetics, and printing can cause water pollution [1,2]. Dye color is a major attraction for all textile materials and is therefore widely used in these industries [3]. The textile dyeing industry has been identified as a major source of water pollution, with typically 15-50% of textile

Synthesis of GCN and x% AgGCN Composite Catalysts
The bare GCN was fabricated by the calcination method [26]. First, 2 g of melamine was heated in a covered crucible at 500 • C for 3 h with a heating rate of 3 • C min −1 . The reaction was cooled to atmospheric temperature after which the yellow solid compound was ground into a fine powder. The fabricated g-C 3 N 4 catalyst is called GCN. The impregnation method was used to fabricate AgGCN composite photocatalysts. First, 1 g of GCN nanosheets was dispersed in a 30 mL solution with a 1:1 ratio of water and ethanol for 30 min with constant stirring. After the solution was stirred for 1 h the calculated amount of 5% AgNO 3 was added to the above solution. Finally, the resulting mixture was dried at 70 • C for 6 h followed by calcination at 350 • C for 2 h. Different percentages of x% Ag (x = 1, 3, 5, and 7% wt.%) were added to g-C 3 N 4 , resulting in samples labeled as 1% AgGCN, 3% AgGCN, 5% AgGCN, and 7% AgGCN, respectively.

Characterizations of Materials
The phase formation and crystal structure of the fabricated bare and composite photocatalysts were analyzed by XRD (Miniflex, Rigaku, Tokyo, Japan). FT-IR spectroscopy was performed using a Thermo Fisher iS50 spectrometer (Thermo Fisher Scientific India Pvt Ltd., Mumbai, India). UV-DRS analysis was carried out using (JASCO-V750, Anatek Services Private Ltd., Mumbai, India). The morphology of the bare GCN and 5% AgGCN composite catalyst was characterized using scanning electron microscopy (SEM, Hitachi S-4800, Tokyo, Japan) coupled with an energy dispersive spectrum (EDS) analyzer.

Photocatalytic Activity Measurement
All the samples were evaluated as synthesized for photocatalytic activity by measuring their ability to degrade methyl orange in an aqueous solution under sunlight irradiation. Photocatalytic experiments were performed using 30 mg of bare GCN and x% AgGCN (x = 1, 3, 5, and 7 wt.%) composite photocatalysts in 100 mL of 20 ppm MO aqueous dye solution. The dye solution was kept stirred in the dark for 30 min before irradiation. The dye solution was exposed to sunlight and constantly stirred. An amount 3 mL of the MO dye solution was taken at each subsequent 15 min interval to determine the concentration of degraded organic contaminants. A centrifugation process can be used to separate the photocatalyst from the dye solution. The UV-visible spectrophotometer was found to be an effective tool for estimating concentrations of dye solutions by recording the intensity of the absorption band of MO at 464 nm. The intensity of solar light measured with a TES Datalogging solar power meter was found to be 95 mW/cm 2 . The % degradation, apparent rate constant (k app ), and half-life period (t 1/2 ) were determined using the following equations (Equations (1)-(3)) [27]: The apparent rate constant (k app ) C 0 represents the initial concentration, while C t represents the dye's concentration at time t.

XRD Analysis
XRD measurements were used to study the purity and phase formation of the asprepared materials. Figure 1 shows the XRD patterns of bare GCN and x% Ag-impregnated GCN (x = 1, 3, 5, and 7 wt.%) composite photocatalysts. The XRD patterns of both the pure GCN and x% AgGCN composites displayed two major peaks at 12.9 • and 27.47 • , characteristic of GCN (JCPDS 87-1526). These findings are in good agreement with previous XRD patterns [28,29].

XRD Analysis
XRD measurements were used to study the purity and phase formation of the asprepared materials. Figure 1 shows the XRD patterns of bare GCN and x% Ag-impregnated GCN (x = 1, 3, 5, and 7 wt.%) composite photocatalysts. The XRD patterns of both the pure GCN and x% AgGCN composites displayed two major peaks at 12.9° and 27.47°, characteristic of GCN (JCPDS 87-1526). These findings are in good agreement with previous XRD patterns [28,29]. The diffraction peaks at 12.9° and 27.47° correspond to the (100) and (002) planes of s-triazine, respectively, with a planar distance of 0.67 nm and 0.32 nm reflective of its inplane structural repeating unit and structural packing arrangement [30]. The presence of Ag species did not affect the crystal structure of the GCN photocatalyst, as no prominent diffraction peaks of other phases or contaminants were found in the composite sample [31]. The diffraction intensity of the 27.47° peak decreases with increasing Ag content on GCN. This results in good agreement with previous literature reports [29,31]. Note that the diffraction peaks related to Ag in the AgGCN composite photocatalyst are not present in all XRD patterns. This could be attributed to the low Ag loading due to the high dilution effect of Ag on the GCN surface, which resulted in XRD analysis results below the detection limit [29,31]. Accordingly, the SEM/EDS analysis shows that there is Ag loading on the GCN surface. Figure 2 shows the FT-IR spectra of the surface characterization of as-prepared bare GCN and x% AgGCN (x = 1, 3, 5, and 7 wt.%) composite photocatalysts. Aromatic C=N and C-N stretching vibrations involve absorption bands at 1242, 1327, 1568, 1408, and 1639 cm −1 [32]. The bending vibration of the s-triazine unit is represented by a peak at 809 cm −1 [33]. The peaks between 3000 and 3300 cm −1 are attributed to stretching vibrations of N-H and O-H groups [34][35][36][37][38][39]. After the addition of Ag, all these characteristic FT-IR peaks indicate that the general structure of GCN is unchanged [40]. The peak intensity of the FT-IR spectra slightly decreased with increasing Ag loading compared to the spectra of bare GCN. This result suggests that the Ag is highly dispersed on the GCN surface. This finding is consistent with previous studies [29,41]. The diffraction peaks at 12.9 • and 27.47 • correspond to the (100) and (002) planes of s-triazine, respectively, with a planar distance of 0.67 nm and 0.32 nm reflective of its in-plane structural repeating unit and structural packing arrangement [30]. The presence of Ag species did not affect the crystal structure of the GCN photocatalyst, as no prominent diffraction peaks of other phases or contaminants were found in the composite sample [31]. The diffraction intensity of the 27.47 • peak decreases with increasing Ag content on GCN. This results in good agreement with previous literature reports [29,31]. Note that the diffraction peaks related to Ag in the AgGCN composite photocatalyst are not present in all XRD patterns. This could be attributed to the low Ag loading due to the high dilution effect of Ag on the GCN surface, which resulted in XRD analysis results below the detection limit [29,31]. Accordingly, the SEM/EDS analysis shows that there is Ag loading on the GCN surface. Figure 2 shows the FT-IR spectra of the surface characterization of as-prepared bare GCN and x% AgGCN (x = 1, 3, 5, and 7 wt.%) composite photocatalysts. Aromatic C=N and C-N stretching vibrations involve absorption bands at 1242, 1327, 1568, 1408, and 1639 cm −1 [32]. The bending vibration of the s-triazine unit is represented by a peak at 809 cm −1 [33]. The peaks between 3000 and 3300 cm −1 are attributed to stretching vibrations of N-H and O-H groups [34][35][36][37][38][39]. After the addition of Ag, all these characteristic FT-IR peaks indicate that the general structure of GCN is unchanged [40]. The peak intensity of the FT-IR spectra slightly decreased with increasing Ag loading compared to the spectra of bare GCN. This result suggests that the Ag is highly dispersed on the GCN surface. This finding is consistent with previous studies [29,41].

UV-DRS Analysis
The optical properties of all the fabricated materials were investigated from UV-Vis diffuse reflectance spectra. The UV-Vis DRS spectra of the bare GCN and x% AgGCN (x = 1, 3, 5, and 7 wt.%) composite photocatalysts are shown in Figure 3. A typical semiconductor absorption feature can be seen in the bare GCN. The spectrum reveals that the optical absorption ranges from ultraviolet to visible light, with absorption bands ranging from 400 to 800 nm, corresponding to the characteristic bandgap of pure GCN. The visible light absorption intensity of the AgGCN photocatalyst is further enhanced by the surface plasmon resonance (SPR) of Ag and is higher than that of pristine GCN [42]. AgGCN photocatalysts with strong visible light responsiveness enhance photocatalytic activity in direct solar light. The bandgaps of bare GCN and x% AgGCN composite catalysts were determined using the formula Eg = 1240/λ, where λ is the cutoff wavelength [43]. The bandgap values of materials were calculated to be 2.60, 2.35, 2.34, 2.30, and 2.36 eV for the pure GCN, 1% AgGCN, 3% AgGCN, 5% AgGCN, and 7% AgGCN composite photocatalysts, respectively.

UV-DRS Analysis
The optical properties of all the fabricated materials were investigated from UV-Vis diffuse reflectance spectra. The UV-Vis DRS spectra of the bare GCN and x% AgGCN (x = 1, 3, 5, and 7 wt.%) composite photocatalysts are shown in Figure 3. A typical semiconductor absorption feature can be seen in the bare GCN. The spectrum reveals that the optical absorption ranges from ultraviolet to visible light, with absorption bands ranging from 400 to 800 nm, corresponding to the characteristic bandgap of pure GCN. The visible light absorption intensity of the AgGCN photocatalyst is further enhanced by the surface plasmon resonance (SPR) of Ag and is higher than that of pristine GCN [42]. AgGCN photocatalysts with strong visible light responsiveness enhance photocatalytic activity in direct solar light. The bandgaps of bare GCN and x% AgGCN composite catalysts were determined using the formula Eg = 1240/λ, where λ is the cutoff wavelength [43].

UV-DRS Analysis
The optical properties of all the fabricated materials were investigated from UV-Vis diffuse reflectance spectra. The UV-Vis DRS spectra of the bare GCN and x% AgGCN (x = 1, 3, 5, and 7 wt.%) composite photocatalysts are shown in Figure 3. A typical semiconductor absorption feature can be seen in the bare GCN. The spectrum reveals that the optical absorption ranges from ultraviolet to visible light, with absorption bands ranging from 400 to 800 nm, corresponding to the characteristic bandgap of pure GCN. The visible light absorption intensity of the AgGCN photocatalyst is further enhanced by the surface plasmon resonance (SPR) of Ag and is higher than that of pristine GCN [42]. AgGCN photocatalysts with strong visible light responsiveness enhance photocatalytic activity in direct solar light. The bandgaps of bare GCN and x% AgGCN composite catalysts were determined using the formula Eg = 1240/λ, where λ is the cutoff wavelength [43]. The bandgap values of materials were calculated to be 2.60, 2.35, 2.34, 2.30, and 2.36 eV for the pure GCN, 1% AgGCN, 3% AgGCN, 5% AgGCN, and 7% AgGCN composite photocatalysts, respectively.    Figure 4a-b, the bare GCN revealed a layered structure of irregularly shaped sheets made from melamine. The induction of Ag leads to the formation of similar sheets like layered structures and some agglomeration structure was observed. This was similarly observed in previous literature reports [31].

SEM/EDS Analysis
Figure 4a-d shows the FE-SEM image of the bare GCN and 5% AgGCN composite photocatalysts. As shown in Figure 4a-b, the bare GCN revealed a layered structure of irregularly shaped sheets made from melamine. The induction of Ag leads to the formation of similar sheets like layered structures and some agglomeration structure was observed. This was similarly observed in previous literature reports [31]. The chemical composition of bare GCN and the most active 5% AgGCN composite catalysts were recorded using the EDS. Figure 5a-d shows the SEM image, elemental mapping, and EDS spectrum of the bare GCN photocatalyst. The elemental mapping of the 5% AgGCN nanocomposite reveals that the C, N, and Ag species are shown in Figure 6ad. The Ag is uniformly distributed throughout the GCN surface. The chemical compositions of 5% AgGCN composite photocatalysts containing C, N, and Ag have been successfully evaluated with the EDS and are presented in the table (inset) shown in Figure 6e. This result suggests that the sample is of high purity and free of other impurities, providing evidence that the 5% Ag NPs were successfully assembled with GCN nanosheets.  Figure 6e. This result suggests that the sample is of high purity and free of other impurities, providing evidence that the 5% Ag NPs were successfully assembled with GCN nanosheets.
The physico-chemical characterization reveals the successful formation of AgGCN composite photocatalysts. From XRD, the diffraction intensity of the 27.47 • peak decreases with increasing Ag content on GCN. However, in the FT-IR study, after the addition of Ag, all the characteristic FT-IR peaks of GCN are unchanged. From SEM analysis, the bare GCN revealed a layered structure with irregularly shaped sheets, whereas AgGCN leads to the formation of similar sheets like layered structures with some agglomeration. The EDS and elemental mapping confirm the presence of Ag in AgGCN. The visible light absorption intensity of AgGCN photocatalysts is higher than that of pristine GCN due to the surface plasmon resonance (SPR) of Ag which makes this photocatalyst more active under solar light.
5% AgGCN nanocomposite reveals that the C, N, and Ag species are shown in Fig  d. The Ag is uniformly distributed throughout the GCN surface. The chemical c tions of 5% AgGCN composite photocatalysts containing C, N, and Ag have been fully evaluated with the EDS and are presented in the table (inset) shown in Fi This result suggests that the sample is of high purity and free of other impurities, ing evidence that the 5% Ag NPs were successfully assembled with GCN nanosh  The physico-chemical characterization reveals the successful formation of composite photocatalysts. From XRD, the diffraction intensity of the 27.47° peak d with increasing Ag content on GCN. However, in the FT-IR study, after the add Ag, all the characteristic FT-IR peaks of GCN are unchanged. From SEM analysis, GCN revealed a layered structure with irregularly shaped sheets, whereas AgGC to the formation of similar sheets like layered structures with some agglomerat EDS and elemental mapping confirm the presence of Ag in AgGCN. The visible sorption intensity of AgGCN photocatalysts is higher than that of pristine GCN d

Photocatalytic Activity of Bare GCN and x% AgGCN Composite Photocatalysts
To investigate the effect of initial dye concentration on degradation rate, the experiments were performed using 5% AgGCN (30 mg) for 75 min. The dye concentration was varied from 20 to 50 ppm. The corresponding results are shown in Figure 7. As the dye concentration increased from 20 ppm to 50 ppm, the rate of MO degradation decreased significantly from 99% to 52%. The presence of so many dye molecules prevent light reaching across the catalyst surface [1]. The initial dye concentration was optimized at 20 ppm and was used for further studies.  Figure 8a displays the photocatalytic performance of the prepared bare GCN and x% AgGCN composite photocatalysts in the degradation of the methyl orange dye aqueous solution under solar irradiation. As a result of solar light irradiation, the experiments demonstrated that the dye solution concentration did not change in the absence of the photocatalyst and revealed that MO dye is not degraded by solar irradiation without a photocatalyst. It is clear that direct photolysis is not powerful enough to effectively degrade aqueous MO dyes. Before the photocatalytic process, the suspension was placed in the dark, the adsorption-desorption equilibrium was measured, and then the sunlight irradiation was started. The bare GCN photocatalyst showed that 26% of the MO dye was degraded after 75 min of sunlight irradiation. Figure 8b reveals that the degradation activities of the prepared 1%, 3%, 5%, and 7% AgGCN composite photocatalysts were 49%, 77%, 99%, and 96%, respectively. Both the 5% AgGCN and 7%AgGCN composites photocatalysts showed significantly enhanced photocatalytic degradation of MO dyes under solar light irradiation when compared with other fabricated bare and composite photocatalysts. The efficiency of the fabricated photocatalysts for the degradation of MO dye is in the order of 5% AgGCN > 7% AgGCN > 3% AgGCN > 1% AgGCN > GCN. The photocatalytic efficacy is improved after Ag modification, which has a significant effect on carrier charge transfer. Figure 8c    It is clear that direct photolysis is not powerful enough to effectively degrade aqueous MO dyes. Before the photocatalytic process, the suspension was placed in the dark, the adsorption-desorption equilibrium was measured, and then the sunlight irradiation was started. The bare GCN photocatalyst showed that 26% of the MO dye was degraded after 75 min of sunlight irradiation. Figure 8b reveals that the degradation activities of the prepared 1%, 3%, 5%, and 7% AgGCN composite photocatalysts were 49%, 77%, 99%, and 96%, respectively. Both the 5% AgGCN and 7%AgGCN composites photocatalysts showed significantly enhanced photocatalytic degradation of MO dyes under solar light irradiation when compared with other fabricated bare and composite photocatalysts. The efficiency of the fabricated photocatalysts for the degradation of MO dye is in the order of 5% AgGCN > 7% AgGCN > 3% AgGCN > 1% AgGCN > GCN. The photocatalytic efficacy is improved after Ag modification, which has a significant effect on carrier charge transfer. Figure 8c displays the gradual degradation of the MO dye solution in the 5% AgGCN composite photocatalyst with increasing irradiation time (15 min constant interval), as evidenced by the decrease in the maximum absorption band intensity at 464 nm. Figure 8d shows the corresponding results of the K aap value of MO dye degradation using the resulting bare GCN and x% AgGCN composite photocatalysts. As shown in Figure 8d, 5% AgGCN composite photocatalysts have the highest rate constant of 0.05905 min −1 , which is 14.83, 6.63, 3.02, and 1.41 times higher than that of pure GCN (0.00398 min −1 ), 1% AgGCN (0.00889 min −1 ), 3% AgGCN (0.01954 min −1 ), and 7% AgGCN (0.04178 min −1 ), respectively. The calculated half-life period (t 1/2 ) values in the MO dye degradation using the 5% AgGCN composite catalyst (11.73 min) were found to be higher than that of 7% AgGCN (16.58 min), 3% AgGCN (34.47 min), 1%AgGCN (77.88 min), and bare GCN (173.95). All the fabricated materials were well linearly fitted with the relationship coefficient value (R 2 ≈ 1) and the data obtained were fitted to a pseudo-first-order kinetic model. The calculated R 2 values for the as-obtained bare GCN and 1%, 3%, 5%, and 7% AgGCN composite photocatalysts throughout the MO dye degradation reaction were 0.9955, 0.9797, 0.9720, 0.8647, and 0.8838, respectively.  Figure 8d shows the corresponding results of the Kaap value of MO dye degradatio using the resulting bare GCN and x% AgGCN composite photocatalysts. As shown Figure 8d, 5% AgGCN composite photocatalysts have the highest rate constant of 0.0590 min −1 , which is 14.83, 6.63, 3.02, and 1.41 times higher than that of pure GCN (0.0039 min −1 ), 1% AgGCN (0.00889 min −1 ), 3% AgGCN (0.01954 min −1 ), and 7% AgGCN (0.0417 min −1 ), respectively. The calculated half-life period (t1/2) values in the MO dye degradatio using the 5% AgGCN composite catalyst (11.73 min) were found to be higher than that 7% AgGCN (16.58 min), 3% AgGCN (34.47 min), 1%AgGCN (77.88 min), and bare GC (173.95). All the fabricated materials were well linearly fitted with the relationship coeffi cient value (R 2 ≈ 1) and the data obtained were fitted to a pseudo-first-order kinetic mode The calculated R 2 values for the as-obtained bare GCN and 1%, 3%, 5%, and 7% AgGC composite photocatalysts throughout the MO dye degradation reaction were 0.995 0.9797, 0.9720, 0.8647, and 0.8838, respectively.
An important factor to consider when developing a practical strategy is the photo stability of the catalyst. Figure 9 shows the recycling stability test of the most active 5 AgGCN composite photocatalyst. The photocatalytic degradation activity of the 5% Ag GCN catalyst showed sustained performance of the MO dye over five consecutive recy cling cycles with the same solar light illumination. An important factor to consider when developing a practical strategy is the photostability of the catalyst. Figure 9 shows the recycling stability test of the most active 5% AgGCN composite photocatalyst. The photocatalytic degradation activity of the 5% Ag-GCN catalyst showed sustained performance of the MO dye over five consecutive recycling cycles with the same solar light illumination.
The 5% AgGCN nanocomposite appears to have good stability and reusability, as only negligible efficiency loss is observed after the fourth and fifth photocatalysis cycles. A slight decrease in photolytic performance (99-87%) occurred. The present study is compared with recently reported studies on the photocatalytic degradation of AgGCN composite catalysts given in Table 1.

Catalytic Mechanism
The as-obtained most active 5% AgGCN composite photocatalyst has the potential to treat wastewater in an environmentally friendly manner. The involvement of key reactive species in photocatalytic systems was studied to determine the effects of different radical scavengers on the photodegradation of MO dyes ( Figure 10). In general, the photodegradation mechanism involving multiple reactive species was performed using ammonium oxalate (AO), tert-butanol (BuOH), and p-benzoquinone (BQ) as trapping agents for h + , • OH, and O 2 •− [1]. Meanwhile, BQ was used for the O 2 •− scavenger, and the decomposition performance was lower compared to other scavengers. As evident from Figure 10, the photocatalysis efficiency of 5% AgGCN was significantly reduced in the presence of BQ. This suggests that O 2 •− was the predominant reactive species. The introduction of the • OH and h + scavengers BuOH and AO reduced the photocatalytic activity of the 5%AgGCN composite catalyst to 59% and 71%, respectively, from 99% (without scavenger). The scavenger study results indicate that O 2 •− radicals are the main contributors to the enhanced photocatalytic performance of the system [42]. The 5% AgGCN nanocomposite appears to have good stability and reusability, as only negligible efficiency loss is observed after the fourth and fifth photocatalysis cycles. A slight decrease in photolytic performance (99-87%) occurred. The present study is compared with recently reported studies on the photocatalytic degradation of AgGCN composite catalysts given in Table 1.

Catalytic Mechanism
The as-obtained most active 5% AgGCN composite photocatalyst has the potential to treat wastewater in an environmentally friendly manner. The involvement of key reactive species in photocatalytic systems was studied to determine the effects of different radical scavengers on the photodegradation of MO dyes ( Figure 10). In general, the photodegradation mechanism involving multiple reactive species was performed using ammonium oxalate (AO), tert-butanol (BuOH), and p-benzoquinone (BQ) as trapping agents for h + , • OH, and O2 •− [1]. Meanwhile, BQ was used for the O2 •− scavenger, and the decomposition performance was lower compared to other scavengers. As evident from Figure 10, the photocatalysis efficiency of 5% AgGCN was significantly reduced in the presence of BQ. This suggests that O2 •− was the predominant reactive species. The introduction of the • OH and h + scavengers BuOH and AO reduced the photocatalytic activity of the 5%AgGCN composite catalyst to 59% and 71%, respectively, from 99% (without scavenger). The scavenger study results indicate that O2 •− radicals are the main contributors to the enhanced photocatalytic performance of the system [42].   Based on the above scavenger results, a possible photocatalytic mechanism of the MO dye under sunlight with the most active 5% AgGCN composite photocatalyst was proposed and is shown in Figure 11. The well-known semiconductor GCN material is stimulated to produce both holes and electrons when exposed to solar light. Modification of Ag enhances the photocatalytic performance of GCN through a combination of both the sur- Based on the above scavenger results, a possible photocatalytic mechanism of the MO dye under sunlight with the most active 5% AgGCN composite photocatalyst was proposed and is shown in Figure 11. The well-known semiconductor GCN material is stimulated to produce both holes and electrons when exposed to solar light. Modification of Ag enhances the photocatalytic performance of GCN through a combination of both the surface plasmon resonance (SPR) effect of Ag and the reduced recombination rate of photogenerated e − /h + pairs [19]. Based on the above scavenger results, a possible photocatalytic mechanism of the MO dye under sunlight with the most active 5% AgGCN composite photocatalyst was proposed and is shown in Figure 11. The well-known semiconductor GCN material is stimulated to produce both holes and electrons when exposed to solar light. Modification of Ag enhances the photocatalytic performance of GCN through a combination of both the surface plasmon resonance (SPR) effect of Ag and the reduced recombination rate of photogenerated e − /h + pairs [19]. Figure 11. A possible photocatalytic mechanism using the 5% AgGCN composite photocatalyst.
The most active 5%AgGCN material produces isolated electron-hole pairs when exposed to sunlight, and electrons are excited into the conduction band (CB) of GCN while holes remain in the valence band (VB). The high Schottky barrier of Ag allows electron transfer from Ag and participation in the reduction reaction at the photocatalytic surface. We investigated the generation of electrons by plasmon-excited Ag and photoexcited Figure 11. A possible photocatalytic mechanism using the 5% AgGCN composite photocatalyst.
The most active 5%AgGCN material produces isolated electron-hole pairs when exposed to sunlight, and electrons are excited into the conduction band (CB) of GCN while holes remain in the valence band (VB). The high Schottky barrier of Ag allows electron transfer from Ag and participation in the reduction reaction at the photocatalytic surface. We investigated the generation of electrons by plasmon-excited Ag and photoexcited GCN sheets. These electrons can react with O 2 to form O 2 •− radicals and catalyze the degradation of the MO dye molecule into CO 2 and H 2 O.

Conclusions
In summary, bare GCN and x% AgGCN composite photocatalysts with various weight percentages (x = 1, 3, 5, and 7 wt.%) were successfully prepared by calcination and simple impregnation methods. The most active 5% AgGCN composite photocatalyst has been demonstrated to have significantly enhanced photocatalytic performance for MO dye degradation compared to other bare and composite photocatalysts. This enhances the photocatalytic performance of 5% AgGCN through a combination of both the surface plasmon resonance (SPR) effect of Ag and the reduced recombination rate of photogenerated e−/h+ pairs. The rate constant value of the 5% AgGCN composite photocatalyst is 14.83 times higher than that of the bare GCN catalyst. Moreover, the photocatalytic degradation performance of the fabricated composite material shows no significant signs of declining even after the fifth cycle. The degradation of dye-contaminated wastewater from the textile industry can be achieved using the high performance of the 5% AgGCN composite photocatalyst. Data Availability Statement: The datasets used or analyzed during the current study are available from the corresponding author upon reasonable request.