<p>Perfluorooctanoic acid (PFOA) has emerged as a&#xa0;new urgent pollutant in aquatic environments due to its high persistence and ecotoxicity. In photocatalytic degradation systems, challenges such as rapid recombination of electron–hole pairs (e⁻/h⁺), short lifespans of reactive oxygen species (ROS), and insufficient ROS generation hinder the efficient degradation of PFOA. This study presents a novel "scallop cage" architecture, constructed using <i>Ulva</i> biochar to create confined spaces that encapsulate the Fe₃O₄/ZnO heterojunction. This approach not only controls the crystal size of the Fe₃O₄/ZnO heterojunction but also confines the degradation reactions to a specific space, significantly shortening the mass transfer distance for ROS and effectively mitigating their rapid deactivation in aqueous-phase degradation processes. Furthermore, the confinement effect enhances the generation of multiple reactive species (·O₂⁻, ·OH, <sup>1</sup>O₂, and h⁺). The optimized FZS@UBC-2 composite photocatalyst achieved a PFOA removal efficiency of 97.53%. In practical applications, FZS@UBC-2 efficiently decomposes PFOA in complex aqueous matrices and can be easily recovered using an external magnetic field. This work not only expands the application of algae-derived biochar in advanced oxidation processes but also offers a sustainable strategy for addressing persistent organic pollutants in aquatic environments.</p> Graphical Abstract <p></p>

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Cage-like ulva biochar confined synthesis of Fe₃O₄/ZnO heterojunction nanoparticles for synergistic adsorption and photocatalytic degradation of PFOA

  • Hua Jing,
  • Daoqiong Zheng,
  • Hao Du,
  • Haojia Zhu,
  • Mengshan Chen,
  • Yingtang Zhou

摘要

Perfluorooctanoic acid (PFOA) has emerged as a new urgent pollutant in aquatic environments due to its high persistence and ecotoxicity. In photocatalytic degradation systems, challenges such as rapid recombination of electron–hole pairs (e⁻/h⁺), short lifespans of reactive oxygen species (ROS), and insufficient ROS generation hinder the efficient degradation of PFOA. This study presents a novel "scallop cage" architecture, constructed using Ulva biochar to create confined spaces that encapsulate the Fe₃O₄/ZnO heterojunction. This approach not only controls the crystal size of the Fe₃O₄/ZnO heterojunction but also confines the degradation reactions to a specific space, significantly shortening the mass transfer distance for ROS and effectively mitigating their rapid deactivation in aqueous-phase degradation processes. Furthermore, the confinement effect enhances the generation of multiple reactive species (·O₂⁻, ·OH, 1O₂, and h⁺). The optimized FZS@UBC-2 composite photocatalyst achieved a PFOA removal efficiency of 97.53%. In practical applications, FZS@UBC-2 efficiently decomposes PFOA in complex aqueous matrices and can be easily recovered using an external magnetic field. This work not only expands the application of algae-derived biochar in advanced oxidation processes but also offers a sustainable strategy for addressing persistent organic pollutants in aquatic environments.

Graphical Abstract