Zinc porphyrin and rhenium complex-based donor-acceptor conjugated porous polymer for visible-light-driven conversion of CO2 to CO

Three-dimensional donor-acceptor conjugated porous polymers based on metal-porphyrin and triazine for highly effective photodegradation of organic pollutants in water

Three-dimensional donor-acceptor (D-A) type conjugated porous polymers (CPPs) was designed and synthesized via imine condensation of copper tetraaminoporphyrin (CuTAPP) as donor and 1,3,5-tris-(4-formyl phenyl) triazine (TFPT) as acceptor, named as CuPT-CPP. The CuPT-CPP possesses a high specific surface area (73.7 m2/g) and excellent photophysical properties. The simultaneous introduction of the organometallic molecules and D-A structures in CuPT-CPP could be broadened the visible-light response range (400-800 nm) and facilitated efficient photogenerated carrier separation and transportation. As heterogeneous photocatalysts, CuPT-CPP has excellent photocatalytic performances under visible light irradiation, leading to excellent model pollutant rhodamine B degradation efficiency up to about 100% in 3 h, it has superb stability and reusability during the photocatalytic processes, and CuPT-CPP also exhibited broad substrate adaptability, which could photocatalytic degradation of methylene blue (MB), methyl orange (MO), and tetracycline hydrochloride (TC). This work indicates that three-dimensional D-A type porphyrin- and triazine-based CuPT-CPP has great potential in the practical application of photocatalysis.

Photocatalytic CO2 Conversion into Solar Fuels Using Carbon-Based Materials-A Review

Carbon materials with elusive 0D, 1D, 2D, and 3D nanostructures and high surface area provide certain emerging applications in electrocatalytic and photocatalytic CO₂ utilization. Since carbon possesses high electrical conductivity, it expels the photogenerated electrons from the catalytic surface and can tune the photocatalytic activity in the visible-light region. However, the photocatalytic efficiency of pristine carbon is comparatively low due to the high recombination of photogenerated carriers. Thus, supporting carbon materials, such as graphene, CNTs (Carbon nanotubes), g-C₃N₄, MWCNs (Multiwall carbon nanotubes), conducting polymers, and its other simpler forms like activated carbon, nanofibers, nanosheets, and nanoparticles, are usually combined with other metal and non-metal nanocomposites to increase the CO₂ absorption and conversion. In addition, carbon-based materials with transition metals and organometallic complexes are also commonly used as photocatalysts for CO₂ reduction. This review focuses on developing efficient carbon-based nanomaterials for the photoconversion of CO₂ into solar fuels. It is concluded that MWCNs are one of the most used materials as supporting materials for CO₂ reduction. Due to the multi-layered morphology, multiple reflections will occur within the layers, thus enhancing light harvesting. In particular, stacked nanostructured hollow sphere morphologies can also help the metal doping from corroding.

Dual-Ligand Ti-MOFs with Push-Pull Effect for Photocatalytic H2 Production

Enhancing the photogenerated electrons transfer efficiency is crucial for photocatalytic reactions. Herein, a dual-ligand-induced push-pull effect was manipulated to intensify the transfer of photogenerated electrons between organic ligands and metal clusters using NH₂-MIL-125(Ti), a kind of Ti-based metal-organic framework (MOF), as the model system. The dual-ligand MOF, NH₂/Cl-MIL-125, was designed and synthesized based on the Hammett constant (σ_m), in which -NH₂ (σ_m = -0.16) and -Cl (σ_m = 0.37) were selected as the electron-pushing group and the electron-pulling group, respectively. Meanwhile, -CH₃ (σ_m = -0.07, electron-pushing) and -H (σ_m = 0, neither electron-pushing nor electron-pulling) were selected as the reference groups to prepare NH₂/CH₃-MIL-125 and NH₂/H-MIL-125, respectively, to validate the electron push-pull effect. NH₂/Cl-MIL-125 (5.32 mmol g^-1 h^-1) exhibits a higher photocatalytic H₂ evolution activity than single-ligand NH₂-MIL-125 (1.93 mmol g^-1 h^-1), NH₂/CH₃-MIL-125 (4.45 mmol g^-1 h^-1), and NH₂/H-MIL-125 (4.73 mmol g^-1 h^-1) under full-spectrum irradiation. The result can be attributed to the electron push-pull effect between -NH₂ and -Cl, which boosts the electron transfer along the ligand-metal-ligand direction. Our dual-ligand-induced push-pull strategy for enhancing the electron transfer may offer some novel insights into the rational design and synthesis of photocatalysts for many other reactions.