Separation Of Electron-hole Pairs Research Articles

Preparation and characterization of Ru-TiO2/PC/Fe3O4 composite catalyst with enhanced photocatalytic performance and magnetic recoverability under simulated solar light.

This research focuses on the development of a novel Ru-doped TiO2/grapefruit peel biochar/Fe3O4 (Ru-TiO2/PC/Fe3O4) composite catalyst, which exhibits exceptional photocatalytic efficacy under simulated solar light irradiation. The catalyst is highly effective in the degradation of rhodamine B (RhB), methylene blue (MB), methyl orange (MO), as well as actual industrial dye wastewater (IDW), and can be recovered magnetically for multiple reuse cycles. Significantly, the PCTRF-100 sample exhibited degradation efficiencies of 99.4% for RhB and 99.8% for MB within 60 min, and 98.04% for MO within 120 min. In the case of actual dye wastewater, a reduction in chemical oxygen demand from 1540 mg L-1 to 784 mg L-1 was achieved within 300 min, corresponding to a degradation rate of 46.81%. The remarkable photocatalytic activity observed is primarily attributed to the synergistic interactions among Ru-TiO2, biochar, and Fe3O4, which effectively facilitate the separation and migration of electron-hole pairs in TiO2.

Strong Metal-Support Interaction Facilitates the Separation of Electron-Hole Pairs at Au13/BiOCl Interface: Insight from Quantum Dynamics.

Focusing on Au13/BiOCl, we investigated the effects of the metal-support interaction (MSI) on the photogenerated charge carrier separation using nonadiabatic molecular dynamic simulations combined with time-domain density functional theory. Our results show that the time scales of electron transfer from the Au13 cluster to BiOCl are distinct depending on the intensity of MSI. Oxygen vacancy (OV) can enhance the interaction between the Au13 cluster and BiOCl, leading to a stronger nonadiabatic (NA) coupling in Au13/BiOCl with an OV system compared to that in a pristine Au13/BiOCl system. The time scale of electron transfer in Au13/BiOCl with the OV system is reduced by a factor of 1.65 compared to that of the pristine Au13/BiOCl system. Our study suggests that the electron transfer can be facilitated by enhancing the MSI and provides valuable principles for the design of high-performance photocatalysts.

Design and Synthesis of Phthalocyanine-Sensitized Titanium Dioxide Photocatalysts: A Dual-Pathway Study.

Phthalocyanine-sensitized TiO2 significantly enhances photocatalytic performance, but the method of phthalocyanine immobilization also plays a crucial role in its performance. In order to investigate the effect of the binding strategy of phthalocyanine and TiO2 on photocatalytic performance, a dual-pathway study has been conducted. On the one hand, zinc-tetra (N-carbonylacrylic) aminephthalocyanine (Pc) was directly grafted onto the surface of Fe3O4@SiO2@TiO2 (FST). On the other hand, Pc was immobilized on a silane coupling agent ((3-aminopropyl) triethoxysilane) grafted onto the surface of the FST. Through photocatalytic experiments on the two types of composite materials synthesized, the results showed that the photocatalyst obtained by directly sensitizing Pc (FSTP) exhibited better performance on rhodamine B(RhB) removal than did the other photocatalyst using the silane coupling agent (FSTAP). Further mechanistic studies showed that directly sensitized FSTP exhibited more efficient photogenerated electron-hole pair separation, whereas FSTAP linked by a silane coupling agent created an additional transport distance that might greatly affect the photogenerated electron transport. Therefore, the dual-pathway research in this work provides new guidance for efficiently constructing phthalocyanine-sensitized TiO2 photocatalysts.

Fabrication of 2D/2D Bi2MoO6/Sx@g-C3N(4-y) type-II heterojunction photocatalyst for enhanced visible-light-mediated degradation of tetracycline in wastewater.

Aquatic biota and human health are seriously threatened by the dramatic rise in antibiotics in environmental matrices. In this regard, the present study aims to improve knowledge of the combined effects of heterojunction design and defect engineering on the photocatalytic degradation of pharmaceuticals in aqueous matrices. Advantageously, the positioning of the valence band (VB) and conduction band (CB) levels of Sx@g-C3N(4-y), being higher than those of Bi2MoO6, demonstrates the feasibility of forming a type-II heterojunction between these materials. Initially, S and N defects were inserted in S-doped g-C3N4 through an alkali-assisted calcination method (referred to as Sx@g-C3N(4-y)), as affirmed by the reduced concentrations of S and N in the end product. Thereafter, the Bi2MoO6/Sx@g-C3N(4-y) photocatalysts (referred to as BSxNy) were synthesized via a solvothermal method followed by calcination. Among the prepared samples, the integration of 10% Sx@g-C3N(4-y) with Bi2MoO6 (referred to as BSxNy (II)) demonstrated superior photocatalytic performance. Under optimal conditions, BSxNy (II) achieved a remarkable 92.4% degradation efficiency of tetracycline (TCL) in an aqueous solution after 60 min. The degradation rate of BSxNy (II) transcended that of pristine Sx@g-C3N(4-y) and Bi2MoO6 by 4.86 and 3.41 times, respectively. The higher number of active sites and the greater electron-hole pair separation are responsible for this improvement in the rate of TCL degradation. The photocatalyst also exhibited remarkable thermal/chemical stability and possessed reusability, as noted by 84% TCL degradation TCL up to 5 cycles. The radical scavenging experiment indicated O2˙- as the primary contributor towards TCL degradation, with h+ and ˙OH playing a secondary role. Additionally, a seed germination experiment used to measure phytotoxicity determined that the treated effluent was non-phytotoxic, making it suitable for irrigation.

A Magnetic Photocatalytic Composite Derived from Waste Rice Noodle and Red Mud.

This study is the first to convert two waste materials, waste rice noodles (WRN) and red mud (RM), into a low-cost, high-value magnetic photocatalytic composite. WRN was processed via a hydrothermal method to produce a solution containing carbon quantum dots (CQDs). Simultaneously, RM was dissolved in acid to form a Fe3+ ion-rich solution, which was subsequently mixed with the CQDs solution and underwent hydrothermal treatment. During this process, the Fe3+ ions in RM were transformed into the maghemite (γ-Fe2O3) phase, while CQDs were incorporated onto the γ-Fe2O3 surface, resulting in the CQDs/γ-Fe2O3 magnetic photocatalytic composite. Experimental results demonstrated that the WRN-derived CQDs not only facilitated the formation of the magnetic γ-Fe2O3 phase but also promoted a synergistic interaction between CQDs and γ-Fe2O3, enhancing electron-hole pair separation and boosting the production of reactive radicals such as O2·- and ·OH. Under optimized conditions (pH = 8, carbon loading: 10 wt%), the CQDs/γ-Fe2O3 composite exhibited good photocatalytic performance against methylene blue, achieving a 97.6% degradation rate within 480 min and a degradation rate constant of 5.99 × 10-3 min-1, significantly outperforming RM and commercial γ-Fe2O3 powder. Beyond methylene blue, this composite also effectively degraded common organic dyes, including malachite green, methyl violet, basic fuchsin, and rhodamine B, with particularly high efficiency against malachite green, reaching a degradation rate constant of 5.465 × 10-2 min-1. Additionally, due to its soft magnetic properties (saturation magnetization intensity: 16.7 emu/g, residual magnetization intensity: 2.2 emu/g), the material could be conveniently recovered and reused after photocatalytic cycles. Even after 10 cycles, it retained over 98% recovery and 96% photocatalytic degradation efficiency, underscoring its potential for cost-effective, large-scale photocatalytic water purification.

Construction of CdIn2S4/MXene-TiO2 Z-Scheme Heterojunction for High-Gain Organic Photoelectrochemical Transistor to Achieve Maximized Transconductance at Zero Bias.

Interfacial charge-carrier complexation is a bottleneck problem governing the gating effect of organic photoelectrochemical transistor (OPECT) biosensors. Therefore, it has long been desired to enhance the OPECT gating effect and realize the maximum transconductance at zero bias. In this study, an in situ engineered heterojunction gating and nano-enzymatic catalytic integration of OPECT-colorimetric dual-mode sensing platform is developed for dibutyl phthalate detection. Specifically, highly efficient photoactive CdIn2S4/MXene-TiO2 Z-scheme heterojunction is constructed by two-step in situ engineering to promote effective separation of electron-hole pairs to achieve sensitive gating of poly(ethylene dioxythiophene):poly(styrene sulfonate)-based OPECT. Target-induced rolling circle amplification is used as the signal amplification unit, and Ag@Carbon Sphere (Ag─CS) is used as the signal conditioning element, which on the one hand causes shunting of photogenerated electrons, leading to energy transfer and reduced gating. At the same time, Ag─CS acts as a peroxidase-mimicking nanozyme to oxidize the TMB discoloration. Importantly, the prepared sensor exhibits good selectivity and high sensitivity for the detection of dibutyl phthalate with a detection limit of 0.08 fM and also shows superior detection ability in real water bodies. Therefore, the sensor provides an ideal choice for toxic molecule detection and has a promising application in environmental monitoring and food analysis.

Efficient Photocatalytic Removal of Aqueous Ammonia Nitrogen by g-C3N4/CoP Heterojunctions Under Visible Light Illumination.

With the development of industry, agriculture, and aquaculture, excessive ammonia nitrogen mainly involving ionic ammonia (NH4+) and molecular ammonia (NH3) has inevitable access to the aquatic environment, posing a severe threat to water safety. Photocatalytic technology shows great advantages for ammonia nitrogen removal, such as its efficiency, reusability, low cost, and environmental friendliness. In this study, CP (g-C3N4/CoP) composite materials, which exhibited high-efficiency ammonia nitrogen removal, were synthesized through a simple self-assembly method. For the optimal CP-10 (10% CoP) samples, the removal rate of ammonia nitrogen reached up to 94.8% within 80 min under visible light illumination. In addition, the nitrogen selectivity S(N2) is about 60% for all oxidative products. The high performance of the CP-10 photocatalysts can be ascribed to the effective separation and transmission of electron-hole pairs caused by their heterogeneous structure. This research has significance for the application of photocatalysis for the remediation of ammonia nitrogen wastewater.

A Rod-like Bi2O3 Photocatalyst Derived from Bi-Based MOFs for the Efficient Adsorption and Catalytic Reduction of Cr(VI).

Heavy metal ion pollution poses a serious threat to the natural environment and human health. Photoreduction through Bi-based photocatalysts is regarded as an advanced green technology for solving environmental problems. However, their photocatalytic activity is limited by the rapid recombination of photogenerated e- and h+ pairs and a low photo-quantum efficiency. In this work, an optimal precursor of Bi-based MOFs was identified by using different solvents, and rod-like Bi2O3 materials were derived by in situ oxidation of Bi atoms in the precursor. The adsorption and photocatalytic reduction efficiency of the prepared Bi2O3 materials for Cr(VI) were evaluated under visible light irradiation. The results showed that the prepared materials had a large specific surface area and enhanced visible light absorption. Bi2O3(DMF/MeOH-3)-400 had a large specific surface area and many active adsorption sites, and it had the highest adsorption of Cr(VI) (49.13%) among the materials. Bi2O3(DMF/MeOH-3)-400 also had the highest photocatalytic reduction efficiency, and it achieved 100% removal of 10 mg·L-1 Cr(VI) within 90 min under light. In addition, the material showed remarkable stability after three consecutive photocatalytic cycles. The enhanced photocatalytic performance was mainly attributed to the fast separation of electron-hole pairs and efficient electron transfer in the MOF-derived materials, which was confirmed by electrochemical tests and PL spectroscopy. Reactive species trapping experiments confirmed that electrons were the main active substances; accordingly, a possible photocatalytic mechanism was proposed. In conclusion, this work provides a new perspective for designing novel photocatalysts that can facilitate the removal of Cr(VI) from water.

Customized Ultrathin Oxygen Vacancy-Rich Bi2W0.2Mo0.8O6 Nanosheets Enabling a Stepwise Charge Separation Relay and Exposure of Lewis Acid Sites toward Broad-Spectrum Photothermal Catalysis.

Designing robust photocatalysts with broad light absorption, effective charge separation, and sufficient reactive sites is critical for achieving efficient solar energy conversion. However, realizing these aims simultaneously through a single material modulation approach poses a challenge. Here, a 2D ultrathin oxygen vacancy (Ov)-rich Bi2W0.2Mo0.8O6 solid solution photocatalyst is designed and fabricated to tackle the dilemma through component and structure optimization. Specifically, the construction of a solid solution with ultrathin structure initially facilitates the separation of photoinduced electron-hole pairs, while the introduction of Ov strengthens such separation. In the meantime, the presence of Ov extends light absorption to the NIR region, triggering a photothermal effect that further enhances the charge separation and accelerates the redox reaction. As such, photoinduced charge carriers in the Ov-Bi2W0.2Mo0.8O6 are separated step by step via the synergistic action of 2D solid solution, OV, and solar heating. Furthermore, the introduction of OV exposes surface metal sites that serve as reactive Lewis acid sites, promoting the adsorption and activation of toluene. Consequently, the designed Ov-Bi2W0.2Mo0.8O6 reveals an enhanced photothermal catalytic toluene oxidation rate of 2445µmolg-1h-1 under a wide spectrum without extra heat input. The performance is 9.0 and 3.9 times that of Bi2WO6 and Bi2MoO6 nanosheets, respectively.

Enhanced degradation of tetracycline using ferrihydrite-decorated g-C3N4 via photocatalytic activation of peroxymonosulfate

While antibiotics benefit human health, their misuse and improper disposal harm ecosystems and human health. Thus, a novel Fh/N-g-C3N4 composite photocatalyst was prepared by in situ growing of ferrihydrite (Fh) nanoparticles on the surface of nitrogen-doped g-C3N4 (NCN) for the activation of peroxymonosulfate (PMS), to efficiently photo-degrade tetracycline. In this composite, the separation and transfer efficiency of photo-generated electron-hole pairs were significantly improved, while their recombination was effectively inhibited. The performance of the Fh/NCN-PMS system in degrading tetracycline under visible light demonstrated that 20%Fh/NCN composite photocatalyst, when coupled with PMS at a concentration of 200 mg/L, resulted in a degradation efficiency of 96.9 % for tetracycline at a concentration of 20 mg/L within 30 min. Mechanism investigation revealed that 4 main active species (SO4−, O2−, 1O2 and h+) were involved in tetracycline degradation, with 1O2 and h+ playing a predominant role. Moreover, the Fh/NCN composite demonstrated superior and consistent catalytic performance in activating PMS within a pH range of 4.5 to 10. Notably, the tetracycline degradation efficiency diminished by merely 7.1 % after four cycles of use. This study introduces a new strategy for fabrication of novel photocatalytic-PMS system, providing an efficient and highly stable treatment solution for antibiotic wastewater.

Self-enhanced photoelectrocatalytic removal of Ni-organic complex and Ni recovery by the in-situ forming anodic Ni deposit: P-n junction-driven photocatalytic oxidation and chemical oxidation

The aim of this study was to propose a novel strategy for self-enhanced Ni-organic complex decomplexation and simultaneous Ni recovery based on photoanodic Ni deposition using photoelectrocatalytic (PEC) system. Compared to the conventional PEC process, the deposition of Ni2+ on TiO2 nanorod arrays photoanode led to a 30 % increase in decomplexation efficiency for Ni-ethylenediaminetetraacetic acid (Ni-EDTA). The Ni-EDTA removal rate reached 81.0 ± 0.9 %, and the Ni recovery rate achieved 58.2 ± 0.1 % under a bicarbonate buffer condition at pH 8.5 and a current density of 0.5 mA/cm2. The anodic high-valent Ni deposit can mediate chemical oxidation of Ni-EDTA in the PEC process, which has significant potential for deep mineralization of Ni-EDTA. The formation of Ni-deposited TiO2 film significantly improved PEC activity of photoanode, as revealed by the facilitated interfacial charge transfer, suppressed charge recombination, and improved light harvesting capacity. Moreover, the photocatalytic film that exhibited p-n heterojunction characteristics associated with the accelerated electron-hole pair separation and downward shift in energy bands of TiO2, stimulated ‧OH generation during PEC process, playing a pivotal role in Ni-EDTA decomplexation. Our results highlight the potential of using anodic Ni deposition for the efficient PEC treatment of plating wastewater containing Ni-organic complex.

Development of AgFeO2/g-C3N4/RGO nanocomposites with superior photocatalytic activity and antibacterial properties for wastewater treatment

This research investigates the synergistic photocatalytic efficiency of AgFeO2/g-C3N4/RGO ternary nanocomposites (AGR NCs) for the effective degradation of Reactive Black (RB5) dye and their antibacterial activity, aiming to advance their environmental applications. The nanocomposites were synthesized using a straightforward hydrothermal method and characterized by various techniques including X-ray Diffraction (XRD), X-ray Photoelectron Spectroscopy (XPS), Fourier-transform infrared spectroscopy (FTIR), Scanning Electron Microscopy with Energy Dispersive X-ray Spectroscopy (SEM-EDX), High-resolution Transmission Electron Microscopy (HRTEM), Ultraviolet-Visible Diffuse Reflectance Spectroscopy (UV-DRS) and Photoluminescence (PL) Spectroscopy to assess their structural, morphological, and optical characteristics. The photocatalytic activity was tested by degrading RB5 dye in water. The findings reveal that the AGR NCs exhibit a substantially improved photocatalytic performance compared to AgFeO2 (AgF), AgFeO2/g-C3N4 (AG) and AgFeO2/RGO (AR) nanocomposites. The synergistic effect is attributed to the formation of a heterojunction structure that promotes efficient separation and transfer of photoinduced electron-hole pairs. The reduced graphene oxide (RGO) serves as an excellent electron conductor, further enhancing the charge separation and extending the lifetime of the charge carriers. Photocatalytic experiments revealed that the AGR NCs achieved 95.5 % degradation of RB5 dye within 120 min. The degradation kinetics followed a Pseudo-first-order model, indicating that the efficient and abundant generation of reactive oxygen species (ROS) was responsible for the dye degradation, as confirmed by quenching experiments. Additionally, the AGR NCs exhibit strong antibacterial activity against both Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus). This study provides insights for designing efficient UVA-driven photocatalysts for environmental treatment purposes.

Charge-separated 3D/2D layered heterojunction of NiNb2O6/E-gC3N4 as an efficient photocatalyst for photo-reduction of Cr6+ and photo-oxidation of dyes under visible and sunlight

The major challenge in photocatalysis for environmental remediation is rapid recombination of charge carriers. Recently, the construction of 3D/2D heterojunction is regarded as a viable strategy to overcome this drawback. Towards this objective, 3D NiNb2O6 − 2D E-gC3N4 type-II heterojunction, hitherto not reported, was constructed as a dual catalyst for photo-reduction of Cr6+ to Cr3+ and photo-oxidation of methylene blue (MB), malachite green (MG) and crystal violet (CV) under visible light. After optimizing the parameters, the photocatalytic activity was studied under direct sunlight. Among the prepared catalysts, NG-20 composite (NiNb2O6 −80 % & E-gC3N4 −20 %) exhibits excellent photocatalytic activity in removing 97 % of Cr (VI) under 120 min and degrading 97.4 %, 96.1 % and 98 % of MB, MG and CV respectively in 20 min under direct sunlight. For instance, the rate constant of NG-20 was found to be 4.2 and 5.8 times higher than NiNb2O6 & E-gCN respectively for MB degradation. The superior photocatalytic activity can be attributed to the enhanced charge carrier separation of electron-hole pair due to the construction of 3D/2D heterojunction. Superoxide (0O2−) and hydroxyl (0OH) radicals are the dominant reactive oxygen species (ROS) and a plausible mechanism for photocatalysis is proposed.

Achieving pure-fluorescent color-tunable WOLED through long-range coupling of spatially separated electron–hole pairs

Abstract Color-tunable white organic light-emitting diode (CT-WOLED) with a wide correlated color temperature (CCT) offers numerous advantages in meeting human daily needs related to circadian rhythm. The study of CCT variation trends and the rules governing the expansion of the CCT range will help further improve the performance of such devices. This research proposes an effective strategy for achieving high-efficiency fluorescent CT-WOLEDs through long-range radiative coupling of spatially separated electron–hole pairs. After inserting a 5 nm thick DMAC-DPS layer between the donor (TAPC) and the acceptor (PO-T2T), the charge transfer excitons between TAPC and PO-T2T still exist. As the voltage increases, holes selectively undergo different photophysical processes, resulting in a wide CCT range. This demonstrates the extraordinary potential of spatially separated electron–hole pairs in regulating luminescent properties. By further introducing a bulk exciplex and the conventional red fluorescent dye DCJTB, the device’s efficiency, brightness, and CCT range have been further optimized. Additionally, significant highest occupied molecular orbital energy level difference between the hole transport layer TAPC and the spacer layer facilitates hole accumulation at the TAPC/spacer interface, thereby enhancing the long-range coupling effect. In device E, we achieved a wide CCT range of 2774 K along with a high external quantum efficiency of 9.2%. The results indicate that our proposed long-range coupling strategy not only enables a wide CCT range but also ensures broad spectral emission and high electroluminescence efficiency, providing new possibilities for the field of intelligent lighting.

Understanding How Interfacial Properties Affect the Photovoltage of Metal-Insulator-Semiconductor (MIS) Photoelectrodes

A metal-insulator-semiconductor (MIS) structure is a highly promising photoelectrode architecture to promote photoelectrochemical (PEC) reactions, such as solar water splitting, for the storage of solar energy in chemical fuels that can be transported and used on demand. The semiconductor absorbs photons, creating electron-hole pairs; the insulator facilitates the separation of these excited electron-hole pairs; and the metal collects the desired charge carrier and facilitates its use in the fuel-forming reaction. The ultrathin insulator also stabilizes the semiconductor by serving as a physical barrier that mitigates corrosion by the electrolyte. Despite these attractive features, the MIS fuel-formation rates are significantly limited by the reaction driving force, i.e., the MIS photovoltage. Previous work has shown that the MIS photovoltage can be improved substantially by tuning the insulator properties (e.g., thickness and band structure) and by using metal nanoparticles instead of a planar metal film. These studies explain that tuning the interfacial properties affect the selectivity of carrier transmission into the metal, but there lacks a clear understanding of how carrier selectivity affects the MIS photovoltage. To design MIS structures with enhanced photovoltages, it is critical to understand how interfacial properties affect the MIS photovoltage. Such a fundamental understanding is only possible with a multiphysics continuum model of MIS photoelectrodes.This talk will present our recent efforts to simulate MIS photoelectrodes performing PEC water splitting by using a comprehensive continuum model that accounts for photon absorption, carrier and electrolyte transport, interfacial tunneling, and reaction kinetics. Our simulations have identified how the insulator properties modulate carrier tunneling rates and how these rates impact the MIS photovoltage. Specifically, tuning the insulator properties affects the probability of tunneling, which alters the carrier concentrations at the semiconductor surface. Increasing the carrier concentrations at the semiconductor surface increases the ideal photovoltage (i.e., the difference in quasi-Fermi levels at the semiconductor surface) because of a reduction in the magnitude of the electric field and an increase in the quasi-Fermi level of the minority carrier. This understanding of how insulator properties modulate carrier buildup and, thereby, affect the MIS photovoltage helps identify optimal insulator properties. These predicted optimal properties of the insulator are a large bandgap (resulting in a high band offset with the semiconductor), a high dielectric constant, and a thickness of ~ 1.2 nm. Insulating materials that have a large band offset with the semiconductor are predicted to have high MIS photovoltages by creating an appreciable interfacial tunneling resistance that promotes carrier buildup at the semiconductor surface, and the moderate insulator thickness allows for unimpeded tunneling of the desired carrier. Increasing the insulator thickness beyond its optimal value results in hindered tunneling and a very large concentration of carriers at the semiconductor surface. This extremely large carrier concentration leads to a very large density of charges trapped at interfacial defect states, which are neutralized by a buildup of image charge in the metal. The accumulation of charges across the insulator results in a significant drop in potential that reduces the MIS photovoltage. We find this deleterious potential drop is significantly reduced by using metal nanoparticles, rather than a planar film, because the electrolyte neutralizes most of the trapped charges. This electrolyte charge screening phenomenon reduces the image charge buildup in the metal and, thereby, the drop in potential between the semiconductor and the metal. Thus, MIS structures that use metal nanoparticles (np-MIS) exhibit greater photovoltages than MIS structures with a planar metal film primarily because of a reduction in the potential drop across the insulator. In addition, because of electrolyte charge screening, the optimal insulator thickness in np-MIS structures is larger than that in MIS structures, which enables even further improvements in the photovoltage and provides greater corrosion resistance. Our model predicts the phenomenon of electrolyte charge screening can be further leveraged by using a low coverage of nanoparticles on the insulator (~ 10%), which can be achieved using low loadings and/or small nanoparticles. In all, the results of our study provide significant insights into how interfacial properties affect the MIS photovoltage and provide predictions of the optimal values for the MIS properties. Such understanding is vital for the development of next-generation MIS photoelectrodes that can enable attainment of high rates of solar-to-chemical energy conversion.

(Invited) Stabilization and Activation of Cuprous Oxide Photocathodes for Effective Reduction of Carbon Dioxide

Among representative examples of semiconducting materials for the selective reduction of carbon dioxide to desired small organic molecules (fuels, utility chemicals), there are transition metal oxides (p-type semiconductors), in particular Cu-based oxides, such as Cu2O, CuFeO2, CuBi2O4, CuNb2O6, CuO and Cu2O) that are capable of generating electrons with use of solar visible light. Selectivity of the catalytic systems largely depends on the activing adsorptive (CO2) phenomena and the affinity of catalytic centers to the adsorbed carbon monoxide intermediates leading to their protonation or hydrogenation. Here application of aqueous or water-containing electrolytes is generally preferred. Furthermore, a compromise must be reached between the activity of a catalyst toward hydrogen evolution (water splitting), its ability to promote reductive adsorption of CO2 and to generate moderate coverages of H atoms capable of stabilizing subsequent reduced intermediates.Our interest concentrates on copper(I) oxides but their practical use requires means of stabilization without poisoning or deactivation. To improve stability against photocorrosion, to assure the sufficient electron-hole pair separation, as well as to increase population of electrons in the conduction band, mixed oxide systems combining the p-type semiconductor (e.g. Cu2O) with n-type semiconductors such as TiO2, SrTiO3 or KTaO3 have been proposed. To meet requirements for practical Cu2O-based photocathodes, not only the ability to absorb efficiently visible light and to assure fast interfacial electron transfers but also the stability issues need to be addressed.Contrary to the poor performance of the pristine (bare) copper(I) oxide photocathode, the visible-light-illuminated photoelectrochemical reduction of carbon dioxide has been successfully performed using the p-type Cu2O-semiconductor (deposited onto the transparent fluorine-doped conducting glass electrode) over-coated with the ultra-thin films of various polymer (poly(4-vinyl pyridine, oligoaniline) or polynuclear type materials (titanium, zirconium and tungsten oxides).. In this respect, ultra-thin films of functionalized carbon nanostructures, supramolecular complexes (with nitrogen containing ligands and certain transition metal sites) or robust bacterial biofilms could also be advantageous. For example, A biofilm formed by a strain of Yersinia enterocolitica (Y. enterocolitica) is characterized by high physicochemical stability over a wide pH range (4-10) and temperatures (0-40°C).Also oligoaniline or tungsten oxide over-layers could be fabricated on copper(I) oxide surfaces. Under such conditions, the copper(I) oxide photoelectrode does not change the oxidation state during photoelectrochemical diagnostic experiments. Thus certain robust (not necessarily thin) over-layers could exhibit the effect of stabilization of Cu2O against photocorrosion. Among important issues is the ability of CO2 to undergo adsorption (and activation toward reduction to CO) at both bare and modified surfaces of Cu2O. The proposed bi-layered photocathode has been demonstrated to produce such simple organic fuels as alcohols. Introduction of co-catalytic centers, e.g. palladium in a form of supramolecular complexes could also be advantageous.

Engineering of a N-Doped Anatase/Rutile TiO2 Heterophase Junction via In Situ Phase Growth for Photocatalytic Hydrogen Evolution.

N-doped anatase/rutile TiO2 (AR-N/TiO2) photocatalysts were prepared by combining the strategy of N-doping and in situ heterophase junction generation, which significantly enhanced the photocatalytic H2 generation (1.68 mmol· h-1·g-1). Under monochromatic light at 400 nm, the light exhibits an apparent quantum efficiency of 8.6%. Moreover, this AR-N/TiO2 heterophase junction demonstrates excellent long-term stability when exposed to visible light irradiation. Through the analysis of the electronic structure, the outstanding photocatalytic activity of AR-N/TiO2 can be attributed to the maximized synergetic effect between rutile and anatase for optimal rutile content (21.6%) and enhanced response to visible light due to N-doping. Additionally, the intimate interface formed by the rutile phase grown in situ from the inner core of the anatase phase establishes well-aligned bands, which promote efficient separation of photoinduced electron-hole pairs. Furthermore, the rough surface and porosity of the as-synthesized heterophase junction facilitate an enlarged specific surface area and exposure of active sites, thereby providing more adsorptive and reactive sites that enhance conversion efficiency. This research offers an alternative approach to phase engineering for developing TiO2-based heterophase junction photocatalysts toward efficient hydrogen evolution.

Optimization of band structure by facet engineering to enhance photocatalytic/photothermal synergistic therapy of cobalt sulfide nanosheets

With the rapid development of optics and nanotechnology, optical therapy is recognized as a potential strategy to combat bacterial drug resistance. Unfortunately, the limitation of band structure on the therapeutic effect of photocatalytic nano-antimicrobial materials has become a major challenge in the development of optical therapy. Here, Co9S8 and Co9S8-T200 were prepared by facet engineering design with major exposed facets (311) and (222), respectively. The experimental results demonstrate that the antimicrobial ability of Co9S8-T200 was significantly higher than that of Co9S8 under the excitation of near-infrared light. Theoretical calculations show that the (222) facets can modulate the d-band center of Co9S8-T200 closer to the Fermi energy level. This promotes the binding of the intermediate to the active site. The strong adsorption capacity for O2 and H2O and the high efficiency of electron-hole pair separation facilitate the production of reactive oxygen species dominated by singlet oxygen, and the photocatalytic therapy is effectively enhanced. In addition, Co9S8-T200 has a narrow bandgap to promote photothermal conversion efficiency and light absorption capacity and exhibits excellent photothermal therapy. This work expands new ideas for the development of superior optical antimicrobial agents with synergistic photothermal and photocatalytic therapy.

Facile Synthesis of a Micro–Nano-Structured FeOOH/BiVO4/WO3 Photoanode with Enhanced Photoelectrochemical Performance

In the realm of photoelectrocatalytic (PEC) water splitting, the BiVO4/WO3 photoanode exhibits high electron–hole pair separation and transport capacity, rendering it a promising avenue for development. However, the charge transport and reaction kinetics at the heterojunction interface are suboptimal. This study uses the hydrothermal–electrodeposition–dip coating–calcination method to prepare a microcrystalline WO3 photoanode thin film as the substrate material and combines it with nanocrystalline BiVO4 to form a micro–nano-structured heterojunction photoanode to enhance the intrinsic and surface/interface charge transport properties of the photoanode. Under the condition of 1.23 V vs. RHE, the photoelectric current density reaches 1.09 mA cm−2, which is twice that of WO3. Furthermore, by using a simple impregnation–mineralization method to load the amorphous FeOOH catalyst, a noncrystalline–crystalline composite structure is formed to increase the number of active sites on the surface and reduce the overpotential of water oxidation, lowering the onset potential from 0.8 V to 0.6 V (vs. RHE). The photoelectric current density is further increased to 2.04 mA cm−2 (at 1.23 V vs. RHE). The micro–nano-structure and noncrystalline–crystalline composite structure proposed in this study will provide valuable insights for the design and synthesis of high-efficiency photoelectrocatalysts.

N-defects and P-doping synergistically promote carbon nitride photocatalytic activation of peroxomonosulfate: Triggering the selective generation of 1O2 to degrade 4-Chlorophenol

Metal-based catalyst could be used for efficient peroxymonosulfate (PMS) activation, but inevitably suffered from metal ion leaching. Metal-free graphitic carbon nitride (g-C3N4) materials that can activate PMS are more conducive for practical water treatment. In this study, g-C3N4 with both N-defects and P-doping (CN-NP) was synthesized, which mainly produce singlet oxygen (1O2), and 97 % of 4-CP (4-Chlorophenol) was removed by CN-NP/PMS/Vis reaction system within 60 min. The active species was identified by quenching experiments and electron spin resonance (ESR) tests, and the origin of mainly active species was further verified by the concentration change of PMS during the reaction. It was verified by experiments and theoretical calculations that the introduction of N-defects led to the separation of photoinduced electron-hole pairs and improved photocatalytic activity. Notably, density functional theory (DFT) revealed that both N-defects and P-doping are electron-deficient sites, and P-doping acts as the main PMS adsorption site to promote the loss of electrons from PMS to generate 1O2. In addition, the catalysts developed in this research were anticipated to be applied in real wastewater treatment, contributing to further comprehend the mechanisms of element doping and defect modification in g-C3N4 activating PMS, and providing new insights for the design of PMS-activating catalysts.