Carbon dots capped cerium oxide nanoparticles for highly efficient removal and sensitive detection of fluoride

Since the excess exposure to F^- may induce serious issues to human health, the effective adsorption and sensitive detection of F^- is essential. Therefore, carbon dots (CDs) capped CeO₂ (CeO₂@CDs) was synthesized via hydrothermal treatment of tannic acid and CeCl₃. Due to abundant phenolic hydroxyl are reserved and excellent hydrophilicity, CeO₂@CDs possess high F^- adsorption capacity. The partition coefficient parameters (PC) are determined to be 2.65 L/g, which is comparable with previous work. The kinetics results and adsorption isotherm are consistent with pseudo-second-order model and Freundlich model, respectively, indicating the chemisorption dominate the adsorption, mainly via the ion exchange between hydroxyl and F^-. Since phenolic hydroxyl existed on the CeO₂@CDs, synergetic effect of CDs and CeO₂ contribute to superior ROS eliminating capacity, even at acidic conditions. Moreover, due to the ROS scavenging of CeO₂ @CDs abilities can be potentiated by F^-, colorimetric detection of F^- can be realized via horseradish peroxidase as an indicator. The linear range is 0.3-2.1 mM with limit of detection is 0.13 mg/L. The current results imply that CeO₂@CDs possess potential in both efficient removal and sensitive detection of F^- related contamination issues and elucidation of development to address other anions related issues.

Simultaneous arsenic and fluoride removal using {201}TiO2-ZrO2: Fabrication, characterization, and mechanism

The coexistence of arsenic (As) and fluoride (F) in drinking water is an urgent environmental issue that causes increasing public concerns. The need for effective simultaneous removal of As and F has motived great research efforts. Herein, a novel {201}TiO₂-ZrO₂ composite was synthesized and its application mechanism was explored. Batch adsorption experiments show that the As(III), As(V), and F adsorption followed the pseudo-second-order kinetics with the Langmuir adsorption capacity at 58.5, 21.6, and 13.1 mg/g, respectively. EXAFS and in situ ATR-FTIR results suggested that TiO₂ surface sites were occupied by As(III) and As(V) in bidentate binuclear structures, and ZrO₂ sites preferentially adsorbed As(III) and F in monodentate mononuclear configurations. This molecular structure obtained in the mono-adsorption system was integrated with the charge distribution multisite surface complexation model to accurately predict the As and F co-existing adsorption behaviors. The results in competitive adsorption, regeneration, and application evidenced that the {201}TiO₂-ZrO₂ composite is a promising adsorbent for simultaneous As and F removal.