Accessible New Non-Quantum Dot Cs2PbI2Cl2-Based Photocatalysts for Efficient Hole-Driven Photocatalytic Applications

Efficient, low-cost photocatalysts with mild synthesis conditions and stable photocatalytic behavior have always been the focus in the field of photocatalysis. This study proves that non-quantum-dot Cs2PbI2Cl2-based materials, created by a simple method, can be successfully employed as new high-efficient photocatalysts. The results demonstrate that two-dimensional Cs2PbI2Cl2 perovskite can achieve over three times higher photocatalytic performance compared to three-dimensional CsPbBr3 perovskite. Moreover, the photocatalytic performance of Cs2PbI2Cl2 can be further improved by constructing a heterojunction structure, such as Cs2PbI2Cl2/CsPbBr3. Cs2PbI2Cl2 can connect well with CsPbBr3 through a simple method, resulting in tight bonding at the interface and efficient carrier transfer. Cs2PbI2Cl2/CsPbBr3 exhibits notable 5-fold and 10-fold improvements in photocatalytic performance and rate compared to CsPbBr3. Additionally, Cs2PbI2Cl2/CsPbBr3 demonstrates superb stable catalytic performance, with nearly no decrease in photocatalytic performance after 7 months (RH = 20% ± 10, T = 25 °C ± 5). This study also reveals that the photocatalytic process based on Cs2PbI2Cl2/CsPbBr3 can directly oxidize organic matter using holes, without relying on the generation of intermediate reactive oxygen species from water or oxygen (such as ·OH or ·O2−), showcasing further potential for achieving high photocatalytic efficiency and selectivity in anhydrous/anaerobic catalytic reactions and treating recalcitrant pollutants.


Introduction
Currently, non-metallic and metal oxide (sulfide) semiconductor materials are selected as the most commonly used photocatalysts in the photocatalysis field [1,2].For these photocatalysts, a high-temperature annealing process is usually required, and the wide band gap for the most efficient oxide materials only allows them to be effectively used in the ultraviolet light range [3].In addition, proper control of the nanoparticle size is also necessary.For example, the titanium dioxide (TiO 2 ) particles should be controlled at the 10-30 nm level to ensure a high specific surface area for achieving high photocatalytic performance [4].Moreover, superoxide anions or hydroxyl intermediate radicals are usually required to ensure the smooth progress of the photocatalytic process driven by these oxide catalysts, the performance of which often depends on the level of dissolved oxygen concentration or water molecules [5].In the photocatalysis field, the development of new photocatalysts with a high efficiency, low cost, easy synthesis, non-dependence of intermediate active radicals, and stable photocatalytic behavior has always been a focus of photocatalytic studies [6].
Due to their outstanding photophysical characteristics, perovskite materials have emerged as an effective light-absorbing layer for solar cells, and their solar cells can achieve a photoelectric conversion efficiency of over 26% [7].As suitable candidates for efficient photocatalysts, the prime characteristics of photo-generated carriers and the transmission of carriers are effective [8,9].Among perovskites, the cesium lead bromide (CsPbBr 3 ) perovskite with the suitable tolerance factor of 0.82 is well maintained as the perovskite structure [10][11][12][13].Recently, some attempts have been made to use CsPbBr 3 nanocrystals in the form of quantum dots as different kinds of photocatalysts.During organic reactions, the CsPbBr 3 quantum dot, when used as a catalyst, has been identified to accelerate bond formations, with a high yield [14].As a useful organic pollutant degradation photocatalyst, the CsPbBr 3 quantum dot can effectively degrade the organic compound of 2-Mercaptobenzothiazole [15].Additionally, the construction of CsPbBr 3 -based heterostructures, such as CsPbBr 3 /TiO 2 , has been adopted to reduce the nonradiative recombination of carriers, ultimately improving the photocatalytic performance of CsPbBr 3 [16,17].
To date, studies on CsPbBr 3 or its heterostructure photocatalysts mainly focus on the CsPbBr 3 quantum dot due to its improved stability and quantum size effect [18][19][20][21][22]. Nevertheless, the preparation of quantum dots often involves issues with the cost of preparation and controlling the yield of the high-quantity nanocrystals [23][24][25][26].Additionally, most heterojunction-structured CsPbBr 3 photocatalysts are still involved with a high-temperature preparation process (>300 • C) due to high-temperature-annealed materials, such as TiO 2 [27].Meanwhile, there are some problems, such as the fact that the surface ligands of quantum dots, such as oleyl amine and oleic acid, can eliminate the holes contributing to the photocatalytic processes, or unwanted or uncontrolled photoreactions can occur, ultimately leading to deceased perovskite stability and limited photocatalytic performance [28].To face these issues, it is valuable to further explore new-structured and new-type perovskites for photocatalytic applications.
In this study, non-quantum-dot, Cs 2 PbI 2 Cl 2 -based perovskite materials were investigated as new-type photocatalysts for efficient hole-driven photocatalytic applications.The results indicate that these photocatalysts can be easily obtained at low temperatures (140 • C) by a simple solution method.Compared with CsPbBr 3 , Cs 2 PbI 2 Cl 2 photocatalysts can achieve 3-fold and 7-fold improvements in photocatalytic performance and rate.Moreover, by constructing the Cs 2 PbI 2 Cl 2 /CsPbBr 3 heterostructure structure, due to the tight bonding of interface and suitable valence band, the photocatalytic performance and rate can be further increased by 5 times and 10 times.Additionally, Cs 2 PbI 2 Cl 2 /CsPbBr 3 photocatalysts show excellent photocatalytic stability, with almost no decrease in photocatalytic performance after 7 months in the air and after cyclic catalytic tests.Additionally, the results also reveal that the photocatalytic process based on Cs 2 PbI 2 Cl 2 /CsPbBr 3 can be directly driven by holes, without relying on the generation of intermediate reactive oxygen species generated from water or oxygen (such as •OH or •O 2 − ), which exhibit further potential for achieving the high photocatalytic efficiency and selectivity.

Results and Discussion
In this study, perovskite photocatalysts were synthesized by a simple solution evaporation method.The details of these processes are shown in the Supplementary Materials.The schematic of preparation for CsPbBr 3 , Cs 2 PbI 2 Cl 2 and Cs 2 PbI 2 Cl 2 /CsPbBr 3 perovskite photocatalysts is shown in Figure 1.Taking Cs 2 PbI 2 Cl 2 /CsPbBr 3 as an example, CsCl and PbI 2 (molar ratio of 2:1) are added to dimethyl sulfoxide (DMSO) to prepare the solution, and the pre-prepared non-quantum-dot CsPbBr 3 crystals are subsequently dropped into the solution.The Cs 2 PbI 2 Cl 2 /CsPbBr 3 photocatalyst can be created by evaporating the solution at a temperature of 140 • C.
The XRD measurement was used to detect the crystal structure obtained by the solution evaporation method.As shown in Figure 2a, the diffraction peaks at 2θ = 15.21The XRD measurement was used to detect the crystal structure obtained by the solution evaporation method.As shown in Figure 2a  To observe the CsPbBr3, Cs2PbI2Cl2, and mixed-dimensional Cs2PbI2Cl2/CsPbBr3 crystals, scanning electron microscopy (SEM) was performed.It can be observed that the CsP-bBr3 crystals have a bulk shape (Figure 3a), and the Cs2PbI2Cl2 crystals display a sheet-like accumulation (Figure 3b).After combining the two types of crystals, it was detected that the crystals had a clear sheet-like shape, but the CsPbBr3 crystals were not clearly observed (Figure 3c).To further identify the combination of two crystals, high-resolution transmission electron microscopy (HRTEM) was used.As observed from the results (Figure S2a,b), it can be seen that the Cs2PbI2Cl2/CsPbBr3 crystals have a platelike shape, and the dark spots are distributed on the plane of platelike crystals.The lattice fringes observed from the microregion of Cs2PbI2Cl2/CsPbBr3 crystal (Figure 3d) displayed interplanar d-spacings of 2.88 Å and 4.07 Å (Figure 3e), which was consistent with the lattice parameters of the ( 200) and (110) planes for the two-dimensional Cs2PbI2Cl2 crystal.Meanwhile, the in-   To observe the CsPbBr3, Cs2PbI2Cl2, and mixed-dimensional Cs2PbI2Cl2/CsPbBr3 crystals, scanning electron microscopy (SEM) was performed.It can be observed that the CsP-bBr3 crystals have a bulk shape (Figure 3a), and the Cs2PbI2Cl2 crystals display a sheet-like accumulation (Figure 3b).After combining the two types of crystals, it was detected that the crystals had a clear sheet-like shape, but the CsPbBr3 crystals were not clearly observed (Figure 3c).To further identify the combination of two crystals, high-resolution transmission electron microscopy (HRTEM) was used.As observed from the results (Figure S2a,b), it can be seen that the Cs2PbI2Cl2/CsPbBr3 crystals have a platelike shape, and the dark spots are distributed on the plane of platelike crystals.The lattice fringes observed from the microregion of Cs2PbI2Cl2/CsPbBr3 crystal (Figure 3d) displayed interplanar d-spacings of 2.88 Å and 4.07 Å (Figure 3e), which was consistent with the lattice parameters of the ( 200  To observe the CsPbBr 3 , Cs 2 PbI 2 Cl 2 , and mixed-dimensional Cs 2 PbI 2 Cl 2 /CsPbBr 3 crystals, scanning electron microscopy (SEM) was performed.It can be observed that the CsPbBr 3 crystals have a bulk shape (Figure 3a), and the Cs 2 PbI 2 Cl 2 crystals display a sheet-like accumulation (Figure 3b).After combining the two types of crystals, it was detected that the crystals had a clear sheet-like shape, but the CsPbBr 3 crystals were not clearly observed (Figure 3c).To further identify the combination of two crystals, highresolution transmission electron microscopy (HRTEM) was used.As observed from the results (Figure S2a 3f).The lattice misfit value was calculated as 3% (<5%), which conveniently formed the coherent interface between the different crystal structures according to the semi-coherent dislocation theory [29,30].The small difference in the d-spacings of two crystals implies the small interfacial energy between ( 200 3f).The lattice misfit value was calculated as 3% (<5%), which conveniently formed the coherent interface between the different crystal structures according to the semi-coherent dislocation theory [29,30].The small difference in the d-spacings of two crystals implies the small interfacial energy between (200) of Cs2PbI2Cl2 and (200) of CsPbBr3, which is beneficial for their connection.As a result, the interface of Cs2PbI2Cl2 and CsPbBr3 structures showed a tight connection, and the lattice structures displayed a smooth transition from the (200) of Cs2PbI2Cl2 to (200) of CsPbBr3 (Figure 3e,f).Such a tight connection and smooth transition at the interface between Cs2PbI2Cl2 and CsPbBr3 would effectively reduce the interface carrier transport barrier and facilitate the smooth transmission of photocarriers, thereby reducing the probability of non-radiative recombination and helping to achieve a high photocatalytic performance.As evidenced by XRD and HRTEM results, the Cs2PbI2Cl2/CsPbBr3 mixed-dimensional heterojunction crystal was successfully obtained through a simple solution process.The optical absorption range and bandgap widths of the CsPbBr3, Cs2PbI2Cl2 and Cs2PbI2Cl2/CsPbBr3 heterojunction crystalline materials were assessed using ultravioletvisible absorption spectroscopy (UV-Vis) and ultraviolet-visible diffuse reflectance spectroscopy (UV-Vis DRS).The UV-Vis results revealed that the absorption cutoff edge of CsPbBr3 at approximately 560 nm, while the presence of CsPbBr3 extends the cutoff edge of Cs2PbI2Cl2/CsPbBr3 from 460 nm (Cs2PbI2Cl2) to around 500 nm (Figure 4a).By fitting curves using the Tauc Plot method in the UV-Vis DRS test, the bandgaps of CsPbBr3, Cs2PbI2Cl2, and Cs2PbI2Cl2/CsPbBr3 crystalline materials were determined to be 2.24 eV, 2.87 eV, and 2.54 eV, respectively (Figure 4b).The optical absorption range and bandgap widths of the CsPbBr 3 , Cs 2 PbI 2 Cl 2 and Cs 2 PbI 2 Cl 2 /CsPbBr 3 heterojunction crystalline materials were assessed using ultravioletvisible absorption spectroscopy (UV-Vis) and ultraviolet-visible diffuse reflectance spectroscopy (UV-Vis DRS).The UV-Vis results revealed that the absorption cutoff edge of CsPbBr 3 at approximately 560 nm, while the presence of CsPbBr 3 extends the cutoff edge of Cs 2 PbI 2 Cl 2 /CsPbBr 3 from 460 nm (Cs 2 PbI 2 Cl 2 ) to around 500 nm (Figure 4a).By fitting curves using the Tauc Plot method in the UV-Vis DRS test, the bandgaps of CsPbBr 3 , Cs 2 PbI 2 Cl 2 , and Cs 2 PbI 2 Cl 2 /CsPbBr 3 crystalline materials were determined to be 2.24 eV, 2.87 eV, and 2.54 eV, respectively (Figure 4b).
To evaluate the photocatalytic performance of the CsPbBr 3 , Cs 2 PbI 2 Cl 2 and Cs 2 PbI 2 Cl 2 / CsPbBr 3 as photocatalysts, the representative organic pollutant Rhodamine B was selected as the standard material.Additionally, the change in the absorbance of the Rhodamine B solution under the simulated sunlight illumination (AM 1.5 G) was used to judge the photocatalytic performances (Figure 5a, where C 0 , A 0 , C, and A represent the concentration and absorbance before and after degradation, respectively).The results of sampling every 2 min displayed that, without any photocatalyst, the organic matter showed no decomposition after 10 min under the light exposure.For the CsPbBr 3 -catalyzed case, only a ~10% and ~20% degradation of organic matter occurred during the relatively high catalytic rate stage after 2 and 4 min.In contrast, the Cs 2 PbI 2 Cl 2 catalyst degraded 36.4 and 67.8% of the organic matter within the same time, which showed that the improvement in performance was at least triple.Impressively, Cs 2 PbI 2 Cl 2 /CsPbBr 3 degraded 81.8% and 97.3% of the organic matter after 2 and 4 min, and all organic matter was degraded within 6 min.Although the UV-Vis results showed that Cs 2 PbI 2 Cl 2 and Cs 2 PbI 2 Cl 2 /CsPbBr 3 possessed a narrower light absorption range compared to CsPbBr 3 , they could exhibit an improvement in photocatalytic performance of 3-8 times.To evaluate the photocatalytic performance of the CsPbBr3, Cs2PbI2Cl2 and Cs2PbI2Cl2/CsPbBr3 as photocatalysts, the representative organic pollutant Rhodamine B was selected as the standard material.Additionally, the change in the absorbance of the Rhodamine B solution under the simulated sunlight illumination (AM 1.5 G) was used to judge the photocatalytic performances (Figure 5a, where C0, A0, C, and A represent the concentration and absorbance before and after degradation, respectively).The results of sampling every 2 min displayed that, without any photocatalyst, the organic matter showed no decomposition after 10 min under the light exposure.For the CsPbBr3-catalyzed case, only a ~10% and ~20% degradation of organic matter occurred during the relatively high catalytic rate stage after 2 and 4 min.In contrast, the Cs2PbI2Cl2 catalyst degraded 36.4 and 67.8% of the organic matter within the same time, which showed that the improvement in performance was at least triple.Impressively, Cs2PbI2Cl2/CsPbBr3 degraded 81.8% and 97.3% of the organic matter after 2 and 4 min, and all organic matter was degraded within 6 min.Although the UV-Vis results showed that Cs2PbI2Cl2 and Cs2PbI2Cl2/CsPbBr3 possessed a narrower light absorption range compared to CsPbBr3, they could exhibit an improvement in photocatalytic performance of 3-8 times.This enhancement in performance could also be deduced from the UV-Vis results after 4 min (Figure 5b).The solution catalyzed by CsPbBr3 exhibited strong absorption peaks of organic matter, while the Cs2PbI2Cl2-based solution showed an evident decrease in absorption peaks, and the Cs2PbI2Cl2/CsPbBr3-based solution showed very weak absorption peaks.Furthermore, the degradation rates of the samples were simulated using  To evaluate the photocatalytic performance of the CsPbBr3, Cs2PbI2Cl2 and Cs2PbI2Cl2/CsPbBr3 as photocatalysts, the representative organic pollutant Rhodamine B was selected as the standard material.Additionally, the change in the absorbance of the Rhodamine B solution under the simulated sunlight illumination (AM 1.5 G) was used to judge the photocatalytic performances (Figure 5a, where C0, A0, C, and A represent the concentration and absorbance before and after degradation, respectively).The results of sampling every 2 min displayed that, without any photocatalyst, the organic matter showed no decomposition after 10 min under the light exposure.For the CsPbBr3-catalyzed case, only a ~10% and ~20% degradation of organic matter occurred during the relatively high catalytic rate stage after 2 and 4 min.In contrast, the Cs2PbI2Cl2 catalyst degraded 36.4 and 67.8% of the organic matter within the same time, which showed that the improvement in performance was at least triple.Impressively, Cs2PbI2Cl2/CsPbBr3 degraded 81.8% and 97.3% of the organic matter after 2 and 4 min, and all organic matter was degraded within 6 min.Although the UV-Vis results showed that Cs2PbI2Cl2 and Cs2PbI2Cl2/CsPbBr3 possessed a narrower light absorption range compared to CsPbBr3, they could exhibit an improvement in photocatalytic performance of 3-8 times.This enhancement in performance could also be deduced from the UV-Vis results after 4 min (Figure 5b).The solution catalyzed by CsPbBr3 exhibited strong absorption peaks of organic matter, while the Cs2PbI2Cl2-based solution showed an evident decrease in absorption peaks, and the Cs2PbI2Cl2/CsPbBr3-based solution showed very weak absorption peaks.Furthermore, the degradation rates of the samples were simulated using first-order kinetics, as shown in Figure 5c.According to the simulating results, the This enhancement in performance could also be deduced from the UV-Vis results after 4 min (Figure 5b).The solution catalyzed by CsPbBr 3 exhibited strong absorption peaks of organic matter, while the Cs 2 PbI 2 Cl 2 -based solution showed an evident decrease in absorption peaks, and the Cs 2 PbI 2 Cl 2 /CsPbBr 3 -based solution showed very weak absorption peaks.Furthermore, the degradation rates of the samples were simulated using first-order kinetics, as shown in Figure 5c.According to the simulating results, the degradation rate of CsPbBr 3 was 0.089 min −1 .In contrast, the degradation rates for Cs 2 PbI 2 Cl 2 and the Cs 2 PbI 2 Cl 2 /CsPbBr 3 heterojunction structure could reach 0.600 min −1 and 0.863 min −1 , exhibiting almost a 7-10 times higher photocatalytic rate.In order to better estimate Cs 2 PbI 2 Cl 2 -based photocatalytic performance, the TiO 2 with a 20 nm particle size possessing a relatively high catalytic performance and CsPbBr 3 were selected to construct the heterojunction photocatalyst for comparison (Figure S4).It can be observed that within 4 min, 35% of the organic matter was not catalyzed by the TiO 2 /CsPbBr 3 photocatalyst, and all the organic matter could not be completely catalyzed by TiO 2 /CsPbBr 3 after 10 min.Meanwhile, all Rhodamine B was degraded by the Cs 2 PbI 2 Cl 2 -based photocatalysts within 6-10 min, which implied a high-efficient photocatalytic performance of Cs 2 PbI 2 Cl 2 -based photocatalysts, especially for the Cs 2 PbI 2 Cl 2 /CsPbBr 3 heterojunction photocatalyst.Furthermore, the photogenerated carrier transfer characteristics of the Cs 2 PbI 2 Cl 2 / CsPbBr 3 heterojunction crystals were explored through X-ray photoelectron spectroscopy (XPS) and steady-state photoluminescence (PL) measurement.The XPS measurements (Figure 6a) show that the valence band maximum (EVB) for Cs 2 PbI 2 Cl 2 and CsPbBr 3 are at 1.84 eV and 1.07 eV, which suggests that a suitable band offset exists between Cs 2 PbI 2 Cl 2 and CsPbBr 3 perovskite.As observed from PL measurements (Figure 6b), compared to the fluorescence peak of CsPbBr 3 , the peak of the Cs 2 PbI 2 Cl 2 /CsPbBr 3 heterojunction exhibited a significant increase in fluorescence intensity.This means that the non-radiative recombination of photogenerated carriers in Cs 2 PbI 2 Cl 2 /CsPbBr 3 were more effectively reduced, which was beneficial for providing more active electrons and holes to improve photocatalytic efficiency.within 4 min, 35% of the organic matter was not catalyzed by the TiO2/CsPbBr3 photocatalyst, and all the organic matter could not be completely catalyzed by TiO2/CsPbBr3 after 10 min.Meanwhile, all Rhodamine B was degraded by the Cs2PbI2Cl2-based photocatalysts within 6-10 min, which implied a high-efficient photocatalytic performance of Cs2PbI2Cl2-based photocatalysts, especially for the Cs2PbI2Cl2/CsPbBr3 heterojunction photocatalyst.
Furthermore, the photogenerated carrier transfer characteristics of the Cs2PbI2Cl2/CsPbBr3 heterojunction crystals were explored through X-ray photoelectron spectroscopy (XPS) and steady-state photoluminescence (PL) measurement.The XPS measurements (Figure 6a) show that the valence band maximum (EVB) for Cs2PbI2Cl2 and CsPbBr3 are at 1.84 eV and 1.07 eV, which suggests that a suitable band offset exists between Cs2PbI2Cl2 and CsPbBr3 perovskite.As observed from PL measurements (Figure 6b), compared to the fluorescence peak of CsPbBr3, the peak of the Cs2PbI2Cl2/CsPbBr3 heterojunction exhibited a significant increase in fluorescence intensity.This means that the non-radiative recombination of photogenerated carriers in Cs2PbI2Cl2/CsPbBr3 were more effectively reduced, which was beneficial for providing more active electrons and holes to improve photocatalytic efficiency.To identify carrier mobility, electrochemical impedance spectroscopy (EIS) tests were performed.The results show that the Cs2PbI2Cl2/CsPbBr3 powder exhibited a smaller radius of curvature compared to CsPbBr3 powder (Figure 6c) and TiO2/CsPbBr3 powder (Figure S5a).This indicates that the Cs2PbI2Cl2/CsPbBr3 powder heterojunction material possesses lower carrier transfer resistance, facilitating more rapid and efficient carrier transfer.The results from transient photocurrent response tests demonstrated that the Cs2PbI2Cl2/CsPbBr3 heterojunction could generate a higher current density than that of CsPbBr3 (Figure 6d) and TiO2/CsPbBr3 (Figure S5b), further proving the advantage of To identify carrier mobility, electrochemical impedance spectroscopy (EIS) tests were performed.The results show that the Cs 2 PbI 2 Cl 2 /CsPbBr 3 powder exhibited a smaller radius of curvature compared to CsPbBr 3 powder (Figure 6c) and TiO 2 /CsPbBr 3 powder (Figure S5a).This indicates that the Cs 2 PbI 2 Cl 2 /CsPbBr 3 powder heterojunction material possesses lower carrier transfer resistance, facilitating more rapid and efficient carrier transfer.The results from transient photocurrent response tests demonstrated that the Cs 2 PbI 2 Cl 2 /CsPbBr 3 heterojunction could generate a higher current density than that of CsPbBr 3 (Figure 6d) and TiO 2 /CsPbBr 3 (Figure S5b), further proving the advantage of Cs 2 PbI 2 Cl 2 /CsPbBr 3 heterostructure in carrier transfer and transport.When analyzing our previous research, the high photocatalytic performance of Cs 2 PbI 2 Cl 2 /CsPbBr 3 should be attributed to the reduced non-radiative recombination, the tight connection of heterojunction structure interface (Figure 3), and the matched energy level (Figure 6a).The rapid and efficient carrier transfer will reduce the probability of non-radiative recombination of holes and electrons, thereby facilitating the participation of more photo-generated active electrons and holes in accelerating photocatalytic processes.
To further our understanding of the photocatalytic mechanisms generated by the Cs 2 PbI 2 Cl 2 /CsPbBr 3 , free radical capture experiments were conducted (Figure 7a).Methanol (MT), isopropanol (IPA), and p-benzoquinone (p-BQ) were adopted as the holes (h + ), and hydroxyl radicals (•OH) and superoxide radicals (•O 2 − ) were adopted as free radical scavengers, which usually participate in the photocatalytic process [31,32].According to the results, it could be seen that after 4 min, the degradation rates of organic matter were decreased from 97.3% to 93.8% and 94.4%, respectively, after the addition of IPA and p-BQ scavengers, which showed no significant effect on the degradation processes.This indicated that •OH and •O 2 − were not the primary active species in the photocatalytic reaction driven by Cs 2 PbI 2 Cl 2 /CsPbBr 3 .When MT was added, the degradation rate was significantly decreased to 5.2%, successfully inhibiting the degradation process.Therefore, in the photocatalytic process driven by Cs 2 PbI 2 Cl 2 /CsPbBr 3 , the h + should play the crucial role in the degradation of organic matters.
To further our understanding of the photocatalytic mechanisms generated by the Cs2PbI2Cl2/CsPbBr3, free radical capture experiments were conducted (Figure 7a).Methanol (MT), isopropanol (IPA), and p-benzoquinone (p-BQ) were adopted as the holes (h + ), and hydroxyl radicals (•OH) and superoxide radicals (•O2 − ) were adopted as free radical scavengers, which usually participate in the photocatalytic process [31,32].According to the results, it could be seen that after 4 min, the degradation rates of organic matter were decreased from 97.3% to 93.8% and 94.4%, respectively, after the addition of IPA and p-BQ scavengers, which showed no significant effect on the degradation processes.This indicated that •OH and •O2 − were not the primary active species in the photocatalytic reaction driven by Cs2PbI2Cl2/CsPbBr3.When MT was added, the degradation rate was significantly decreased to 5.2%, successfully inhibiting the degradation process.Therefore, in the photocatalytic process driven by Cs2PbI2Cl2/CsPbBr3, the h + should play the crucial role in the degradation of organic matters.Moreover, electron spin resonance (ESR) tests were further performed to validate the crucial role of h + and •O2 − formed by oxygen/electronics during the photocatalytic processes driven by Cs2PbI2Cl2/CsPbBr3.In the electron spin resonance detection of •O2 − generated from electronics, as shown in Figure 7b, no ESR fluctuation signal appeared under dark conditions and after 5 min of illumination, suggesting that •O2 − was indeed not an active radical species participating in the photocatalytic process.This means that the dissolved oxygen in solution is not an essential requirement to ensure that •O2 − drives the Cs2PbI2Cl2/CsPbBr3-based photocatalytic process.To validate the role of photogenerated − was indeed not an active radical species participating in the photocatalytic process.This means that the dissolved oxygen in solution is not an essential requirement to ensure that •O 2 − drives the Cs 2 PbI 2 Cl 2 /CsPbBr 3 -based photocatalytic process.To validate the role of photogenerated h + , the 2,2,6,6-tetramethylpiperidinooxy (TEMPO) additive was chosen as the capture agent (Figure 7c).As evidenced by the results, under the dark conditions, a high signal peak of TEMPO was detected.When the Cs 2 PbI 2 Cl 2 /CsPbBr 3 heterojunction material generated h + under illumination for 5 min, the h + neutralized with TEMPO, resulting in a significant decrease in the TEMPO signal.These results indicate that the generation of h + is the main factor affecting the photocatalytic reaction driven by Cs 2 PbI 2 Cl 2 /CsPbBr 3 (Figure 7d).Hence, the dissolved oxygen and water molecules are not necessary to form the •O 2 − and •OH intermediate active radicals that guarantee the proceeding of the photocatalytic process.For the hole-driven photocatalytic processes of Cs 2 PbI 2 Cl 2 /CsPbBr 3 , it can provide a high-efficient photocatalytic performance due to avoiding energy loss, benefiting from the absence of the need to form •O 2 − and •OH intermediate radicals.Meanwhile, the hole-direct-driven catalytic process of Cs 2 PbI 2 Cl 2 -based photocatalysts usually has a high oxidation capacity and exhibits a reduction in side reactions, which are very suitable for treating recalcitrant pollutants or the catalytic applications of anhydrous and anaerobic organic chemical reactions.
Furthermore, the Cs 2 PbI 2 Cl 2 /CsPbBr 3 photocatalyst was proven to possess an excellent photocatalytic stability.The performance stability of the Cs 2 PbI 2 Cl 2 /CsPbBr 3 photocatalyst was evaluated through the cyclic catalytic performance and environmental stability tests.The results of the cyclic tests showed that after three cycles, the performance of the Cs 2 PbI 2 Cl 2 /CsPbBr 3 photocatalyst only exhibited minor changes within the time period of 2 to 6 min, but the entire catalytic process was still completed within 6 min (Figure 8a).Meanwhile, attributed to the template stabilization effect of stable two-dimensional Cs 2 PbI 2 Cl 2 perovskite structured on three-dimensional CsPbBr 3 structures, the catalytic performance showed almost no change after the catalyst was placed in normal storage environment (RH = 20% ± 10, T = 25 • C ± 5) for 7 mouths (>5000 h) (Figure 8b).This shows that durable high-catalytic-efficiency characteristics are more suitable for the application of organic chemical catalytic reactions.To further identify the stability, accelerated aging tests were performed (RH= 60%) (Figure S6).After 3 months, a notable attenuation occurred in the reaction rate of CsPbBr 3 -based photocatalytic processes (Figure S6), which decreased from 0.089 min −1 to 0.045 min −1 (attenuation rate: 49.4%; Figure S7).The stability of Cs 2 PbI 2 Cl 2 /CsPbBr 3 exhibited a significant improvement.The reaction rate of Cs 2 PbI 2 Cl 2 /CsPbBr 3 -based photocatalytic processes decreases from 0.863 to 0.669 (attenuation rate: 22.4%; Figure S7), and Cs 2 PbI 2 Cl 2 /CsPbBr 3 could still complete all of the catalytic reaction within 6-8 min (Figure S6).ure 7d).Hence, the dissolved oxygen and water molecules are not necessary to form th •O2 − and •OH intermediate active radicals that guarantee the proceeding of the photocat lytic process.For the hole-driven photocatalytic processes of Cs2PbI2Cl2/CsPbBr3, it ca provide a high-efficient photocatalytic performance due to avoiding energy loss, benefi ing from the absence of the need to form •O2 − and •OH intermediate radicals.Meanwhil the hole-direct-driven catalytic process of Cs2PbI2Cl2-based photocatalysts usually has high oxidation capacity and exhibits a reduction in side reactions, which are very suitab for treating recalcitrant pollutants or the catalytic applications of anhydrous and anaer bic organic chemical reactions.
Furthermore, the Cs2PbI2Cl2/CsPbBr3 photocatalyst was proven to possess an exce lent photocatalytic stability.The performance stability of the Cs2PbI2Cl2/CsPbBr3 phot catalyst was evaluated through the cyclic catalytic performance and environmental stabi ity tests.The results of the cyclic tests showed that after three cycles, the performance the Cs2PbI2Cl2/CsPbBr3 photocatalyst only exhibited minor changes within the time perio of 2 to 6 min, but the entire catalytic process was still completed within 6 min (Figure 8a Meanwhile, attributed to the template stabilization effect of stable two-dimension Cs2PbI2Cl2 perovskite structured on three-dimensional CsPbBr3 structures, the catalyt performance showed almost no change after the catalyst was placed in normal storag environment (RH = 20% ± 10, T = 25 °C ± 5) for 7 mouths (>5000 h) (Figure 8b).This show that durable high-catalytic-efficiency characteristics are more suitable for the applicatio of organic chemical catalytic reactions.To further identify the stability, accelerated agin tests were performed (RH= 60%) (Figure S6).After 3 months, a notable attenuation o curred in the reaction rate of CsPbBr3-based photocatalytic processes (Figure S6), whic decreased from 0.089 min −1 to 0.045 min −1 (attenuation rate: 49.4%; Figure S7).The stabili of Cs2PbI2Cl2/CsPbBr3 exhibited a significant improvement.The reaction rate Cs2PbI2Cl2/CsPbBr3-based photocatalytic processes decreases from 0.863 to 0.669 (attenu ation rate: 22.4%; Figure S7), and Cs2PbI2Cl2/CsPbBr3 could still complete all of the cat lytic reaction within 6-8 min (Figure S6).

Conclusions
In conclusion, the non-quantum-dot, Cs2PbI2Cl2-based perovskites created using ou efficient method are proven to be new-type high-efficient photocatalysts.The catalyt performance of Cs2PbI2Cl2 is three times better than that of the single CsPbB

Conclusions
In conclusion, the non-quantum-dot, Cs 2 PbI 2 Cl 2 -based perovskites created using our efficient method are proven to be new-type high-efficient photocatalysts.The catalytic performance of Cs 2 PbI 2 Cl 2 is three times better than that of the single CsPbBr 3 photocatalyst, and its catalytic rate is seven times higher.The results confirm that the two-dimensional Cs 2 PbI 2 Cl 2 and CsPbBr 3 may be effectively coupled to create a tightly connected and smoothly transitioning heterojunction structure using a simple method.The tight bonding of the interface and suitable valence band maximum of Cs 2 PbI 2 Cl 2 /CsPbBr 3 result in the efficient transfer of carriers and the promotion of photocatalytic process.The photocatalytic performance can be enhanced even further, resulting in a 5-fold and 10-fold increase in catalytic performance and rate.Moreover, Cs 2 PbI 2 Cl 2 /CsPbBr 3 can maintain its excellent photocatalytic performance after long-term environmental tests (>5000 h).
Furthermore, it has been observed that these photocatalysts exhibit exceptional photocatalytic efficiency, as they are capable of directly oxidizing organic substances by the action of h + ions without the need for the production of intermediary reactive oxygen species derived from water or oxygen (such as •OH or •O 2 − ).Directly harnessing holes for oxidation processes can streamline the steps involved in generating reactive oxygen species, effectively minimizing potential energy waste and the formation of reaction by-products.The utilization of hole-driven photocatalytic processes is crucial for enhancing the efficiency and selectivity of photocatalytic reactions.Meanwhile, in this photocatalytic process, the strong direct oxidation capacity of h + makes Cs 2 PbI 2 Cl 2 -based photocatalysts exceptionally effective in treating difficult-to-degrade pollutants.Such applications amply warrant further exploration and research.In summary, this study presents a simple and attainable method to produce catalyst crystals based on Cs 2 PbI 2 Cl 2 , which are not quantum dots.The study also showcases the promising capabilities of these crystals as efficient and long-lasting photocatalysts driven by holes.

Figure 1 .
Figure 1.The schematic of preparation for CsPbBr3, Cs2PbI2Cl2, and mixed-dimensional Cs2PbI2Cl2/CsPbBr3 perovskite photocatalyst.The XRD measurement was used to detect the crystal structure obtained by the solution evaporation method.As shown in Figure2a, the diffraction peaks at 2θ = 15.21°,21.49°, 26.34°, 30.37°, and 34.19° corresponded to the (001), (110), (111), (002), and (210) crystal planes of CsPbBr3 perovskite, comprising the standard cards of CsPbBr3 perovskite (PDF # 18-036).The XRD patterns of Cs2PbI2Cl2 and mixed-dimensional Cs2PbI2Cl2/CsP-bBr3 perovskite are shown in Figure 2b.The diffraction peaks of XRD patterns at 2θ = 9.07°, 21.77°, 27.60°, and 32.35° correspond to the (002), (110), (105), and (202) crystal planes of Cs2PbI2Cl2, which is consistent with our early research.The XRD pattern of mixed compounds is shown in Figure 2b.As demonstrated by the comparison of XRD patterns in Figure S1, the characteristic diffraction peaks representative of Cs2PbI2Cl2 and CsPbBr3 in the Cs2PbI2Cl2/CsPbBr3 compounds shift towards lower and higher angles, respectively.This indicates that the partial substitution of Cl in CsPbBr3 and Br in Cs2PbI2Cl2 may have occurred during the synthesis of Cs2PbI2Cl2/CsPbBr3 compounds.
) and (110) planes for the two-dimensional Cs2PbI2Cl2 crystal.Meanwhile, the interplanar d-spacings of 2.97 Å for the (200) plane of the CsPbBr3 crystal were also observed from the TEM pattern shown on the right side of Figure 3e.The lattice misfit values of
,b), it can be seen that the Cs 2 PbI 2 Cl 2 /CsPbBr 3 crystals have a platelike shape, and the dark spots are distributed on the plane of platelike crystals.The lattice fringes observed from the microregion of Cs 2 PbI 2 Cl 2 /CsPbBr 3 crystal (Figure 3d) displayed interplanar d-spacings of 2.88 Å and 4.07 Å (Figure 3e), which was consistent with the lattice parameters of the (200) and (110) planes for the two-dimensional Cs 2 PbI 2 Cl 2 crystal.Meanwhile, the interplanar d-spacings of 2.97 Å for the (200) plane of the CsPbBr 3 crystal were also observed from the TEM pattern shown on the right side of Figure 3e.The lattice misfit values of (200) of Cs 2 PbI 2 Cl 2 and (200) of CsPbBr 3 were calculated using δ = (d(200) 2D -d(200) 3D )/d(200) 3D (Figure

(
) of Cs 2 PbI 2 Cl 2 and (200) of CsPbBr 3 , which is beneficial for their connection.As a result, the interface of Cs 2 PbI 2 Cl 2 and CsPbBr 3 structures showed a tight connection, and the lattice structures displayed a smooth transition from the (200) of Cs 2 PbI 2 Cl 2 to (200) of CsPbBr 3 Figure 3e,f).Such a tight connection and smooth transition at the interface between Cs 2 PbI 2 Cl 2 and CsPbBr 3 would effectively reduce the interface carrier transport barrier and facilitate the smooth transmission of photocarriers, thereby reducing the probability of non-radiative recombination and helping to achieve a high photocatalytic performance.As evidenced by XRD and HRTEM results, the Cs 2 PbI 2 Cl 2 /CsPbBr 3 mixed-dimensional heterojunction crystal was successfully obtained through a simple solution process.d(200)3D)/d(200)3D (Figure

Figure 7 . 2 −
Figure 7. (a) Free radical capture tests for Cs 2 PbI 2 Cl 2 photocatalysts; (b,c) ESR for •O 2 − generation and h + generation for Cs 2 PbI 2 Cl 2 photocatalysts; and (d) schematic diagram of Cs 2 PbI 2 Cl 2 photocatalytic mechanism of organic matters.Moreover, electron spin resonance (ESR) tests were further performed to validate the crucial role of h + and •O 2 − formed by oxygen/electronics during the photocatalytic processes driven by Cs 2 PbI 2 Cl 2 /CsPbBr 3 .In the electron spin resonance detection of •O 2 − generated from electronics, as shown in Figure 7b, no ESR fluctuation signal appeared under dark conditions and after 5 min of illumination, suggesting that •O 2− was indeed not an active radical species participating in the photocatalytic process.This means that the dissolved oxygen in solution is not an essential requirement to ensure that •O 2 − drives the Cs 2 PbI 2 Cl 2 /CsPbBr 3 -based photocatalytic process.To validate the role of photogenerated h + , the 2,2,6,6-tetramethylpiperidinooxy (TEMPO) additive was chosen as the capture agent (Figure7c).As evidenced by the results, under the dark conditions, a high signal peak of TEMPO was detected.When the Cs 2 PbI 2 Cl 2 /CsPbBr 3 heterojunction material generated h + under illumination for 5 min, the h + neutralized with TEMPO, resulting in a significant decrease in the TEMPO signal.These results indicate that the generation of h + is the main factor affecting the photocatalytic reaction driven by Cs 2 PbI 2 Cl 2 /CsPbBr 3 (Figure7d).Hence, the dissolved oxygen and water molecules are not necessary to form the •O 2