Nitrobenzene inarched carbon nitride nanotube drives efficient directional carriers separation for superior photocatalytic hydrogen production

Photocatalytic Degradation of Aflatoxin B1 and Zearalenone in Cereals: Kinetics, Photoproducts, Mechanisms, and Aquatic Toxicity

Aflatoxin B1 (AFB1) and zearalenone (ZEN) are the most toxic and widely polluted mycotoxins in cereals. Efficient and environmentally friendly technology to eliminate AFB1 and ZEN is important for food safety. In this work, a novel 2-AP-grafted ultrathin porous photocatalyst (denoted as WCN-AP7) was synthesized, characterized, and used for the visible-light-driven photocatalytic degradation of AFB1 and ZEN in cereals. The photocatalytic degradation of mycotoxins by WCN-AP7 nanomaterials in real-world samples demonstrated high efficiency, achieving complete degradation of AFB1 (100%) and near-complete removal of ZEN (89.5%) within 60 min. Furthermore, photodegradation products of AFB1 and ZEN were identified by HPLC-MS/MS, and the main reaction active sites and degradation mechanism were clarified based on radical trapping measurements and density functional theory calculations. The ecotoxicity of the degradation products was predicted, showing the detoxification of AFB1 and ZEN after photodegradation. This work provided a promising visible-light WCN-AP7 nanomaterial for the practical treatment of mycotoxin detoxification in cereals.

Janus Z-scheme heterostructure of ZnIn2S4/MoSe2/In2Se3 for efficient photocatalytic hydrogen evolution

Artificial manipulation of charge separation and transfer are central issues dominating hydrogen evolution reaction triggered via photocatalysis. Herein, through elaborate designing on the architecture, band alignment, and interface bonding mode, a sulfur vacancy-rich ZnIn₂S₄-based (Vs-ZIS) multivariate heterostructure ZnIn₂S₄/MoSe₂/In₂Se₃ (Vs-ZIS/MoSe₂/In₂Se₃) with specific Janus Z-scheme charge transfer mechanism is constructed through a two-step hydrothermal process. Steering by the Janus Z-scheme charge transfer mechanism, photogenerated electrons in the conduction band of MoSe₂ transfer synchronously to the valence band of Vs-ZIS and In₂Se₃, resulting in abundant highly-active photogenerated electrons reserved in the conduction band of Vs-ZIS and In₂Se₃, therefore significantly enhancing the photocatalytic activity of hydrogen evolution. Under visible light irradiation, the optimized Vs-ZIS/MoSe₂/In₂Se₃ with the mass ratio of MoSe₂ and In₂Se₃ to ZnIn₂S₄ at 3 % and 30 %, respectively, performs a high hydrogen evolution rate of 124.42 mmol·g^-1·h^-1, about 43.5-folds of the original ZIS photocatalyst. Besides, an apparent quantum efficiency (AQE) of 22.5 % at 420 nm and favorable durability are also achieved over Vs-ZIS/MoSe₂/In₂Se₃ photocatalyst. This work represents an important development in efficient photocatalysts and donates a sound foundation for the design of regulating charge transfer pathways.

Construction of a heterojunction with fast charge transport channels for photocatalytic hydrogen evolution via a synergistic strategy of Co-doping and crystal plane modulation

Carrier spatial separation efficiency and active electron density are the key factors affecting photocatalytic hydrogen evolution activity. Heterojunction catalysts with fast charge separation and directed electron transport systems were successfully prepared by a synergistic modification strategy of transition metal (Co) doping and crystal plane modulation. The optimized electronic structure and enhanced reaction kinetics enabled unidirectional electron transfer. Photocatalytic results show that CdS(002)/Co-C₃N₄ exhibits remarkable hydrogen evolution activity (991.2 μmol h^-1 g^-1) in the absence of a co-catalyst, which is 37.0 and 3.4 times higher than that of C₃N₄ (26.8 μmol h^-1 g^-1) and Co-C₃N₄ (294.6 μmol h^-1 g^-1), respectively. Density functional theory (DFT) calculations indicate that the enhanced catalytic activity of CdS(002)/Co-C₃N₄ is attributed to the reduced electron-hole recombination rate and the increased electron density at the active site. This work provides a new idea for the design of photocatalysts with directed charge transport channels from the perspective of re-optimizing heterojunctions.

Edge-grafting carbon nitride with aromatic rings for highly-efficient charge separation and enhanced photocatalytic hydrogen evolution

Edge-modification of g-C3N4 induces highly-efficient charge separation through directional transfer of electrons from the center to the edge of the framework.

Regulating polymerization degree of heptazines in carbon nitride with fumaric acid to enhance photocatalytic activity

Carbon nitride (CN) has a wide range of applications in photocatalytic treatment of environmental pollution. One of key challenges in the field is to conveniently prepare CN with tunable band gap towards efficient pollution degradation, which can be overcome by regulating the polymerization degree of its heptazines. Herein, a facile and green strategy to construct CN through co-firing urea, melamine and fumaric acid was reported. By simply inducing appropriate amount of fumaric acid during amidation reaction between fumaric acid and amino groups, the distance between heptazines of CN could be modified to obtain optimized polymerization degree and morphology. Among the considered CN systems, the modulated CN sample with the doped ratio of 2.50: 0.50: 0.03 m urea/m melamine/m fumaric acid (CNF30) displayed remarkable photocatalytic ability due to the largest specific surface area, the lowest photoluminescence emission intensity, and narrowest band gap, which led to the highest 98.0% methyl orange degradation within 60 min under a 10 W lamp and room temperature with the harmless and valuable carboxylic acids products. This study provides a new sight for the design of photocatalysts with tunable band structure towards green and efficient photocatalytic degradation of environmental pollution.