Efficient molecular oxygen activation is crucial for catalytic oxidation reaction, but highly depends on the construction of active sites. In this study, we demonstrate that dual adjacent Fe atoms anchored on MnO2 can assemble into a diatomic site, also called as MnO2-hosted Fe dimer, which activates molecular oxygen to form an active intermediate species Fe(O = O)Fe for highly efficient CO oxidation. These adjacent single-atom Fe sites exhibit a stronger O2 activation performance than the conventional surface oxygen vacancy activation sites. This work sheds light on molecular oxygen activation mechanisms of transition metal oxides and provides an efficient pathway to activate molecular oxygen by constructing new active sites through single atom technology.
The objective of photocatalytic CO2 reduction (PCR) is to achieve high selectivity for a single energy‐bearing product with high efficiency and stability. The bulk configuration usually determines charge carrier kinetics, whereas surface atomic arrangement defines the PCR thermodynamic pathway. Concurrent engineering of bulk and surface structures is therefore crucial for achieving the goal of PCR. Herein, an ultrastable and highly selective PCR using homogeneously doped BiOCl nanosheets synthesized via an inventive molten strategy is presented. With B2O3 as both the molten salt and doping precursor, this new doping approach ensures boron (B) doping from the surface into the bulk with dual functionalities. Bulk B doping mitigates strong excitonic effects confined in 2D BiOCl by significantly reducing exciton binding energies, whereas surface‐doped B atoms reconstruct the BiOCl surface by extracting lattice hydroxyl groups, resulting in intimate B‐oxygen vacancy (B‐OV) associates. These exclusive B‐OV associates enable spontaneous CO2 activation, suppress competitive hydrogen evolution and promote the proton‐coupled electron transfer step by stabilizing *COOH for selective CO generation. As a result, the homogeneous B‐doped BiOCl nanosheets exhibit 98% selectivity for CO2‐to‐CO reduction under visible light, with an impressive rate of 83.64 µmol g−1 h−1 and ultrastability for long‐term testing of 120 h.
A cascade radical cyclization of 2-isocyanoaryl thioethers with H-phosphorus oxides, organoboronic acids, or alkyl radical precursors has been efficiently developed, providing a novel and highly efficient methodology to structurally diverse C2-substituted benzothiazole derivatives with broad functional group tolerance and good yields. This cascade radical process achieves the first cycloaddition of an imidoyl radical from isocyanide to sulfur atom, rending C(sp)-S bond formation.
Smart nanocarriers are of particular interest for highly effective photodynamic therapy (PDT) in the field of precision nanomedicine. Nevertheless, a critical challenge still remains in the exploration of potent PDT treatment against hypoxic tumor. Herein, light‐triggered clustered polymeric vesicles for photoinduced hypoxic tumor ablation are demonstrated, which are able to deeply penetrate into the tumor and simultaneously afford oxygen supply upon light irradiation. Hydrogen peroxide (H2O2) and poly(amidoamine) dendrimer conjugating chlorin e6/cypate (CC‐PAMAM) are coassembled with reactive‐oxygen‐species‐responsive triblock copolymer into the polymeric vesicles. Upon 805 nm irradiation, the vesicles exhibit the light‐triggered thermal effect that is able to decompose H2O2 into O2, which distinctly ensures the alleviation of tumor hypoxia at tumor. Followed by 660 nm irradiation, the vesicles are rapidly destabilized through singlet oxygen‐mediated cleavage of copolymer under light irradiation and thus allow the release of photoactive CC‐PAMAM from the vesicular chambers, followed by their deep penetration in the poorly permeable tumor. Consequently, the light‐triggered vesicles with both self‐supplied oxygen and deep tissue penetrability achieve the total ablation of hypoxic hypopermeable pancreatic tumor through photodynamic damage. These findings represent a general and smart nanoplatform for effective photoinduced treatment against hypoxic tumor.
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