Intensified co-precipitation and ion exchange using an agitated tubular reactor (ATR) for enhanced removal of Cs+ and Sr2+ ions.

• Synthesise composite coagulants for simultaneous removal of Cs+ and Sr2+ ions. • Operating agitated tubular reactor (ATR) in scope of process intensification. • ATR provided maximum removal efficiency of > 96% Cs+ and > 99.9 % Sr2+. • Physical characterisation and pressure filtration analysis also performed. • Smaller specific cake resistances measured for composite flocs than BaSO 4. Composite coagulants were synthesised in both a batch system and an agitated tubular reactor (ATR) using natural clinoptilolite with barite (BaSO 4) co-precipitation for the intensified simultaneous removal of Cs+ and Sr2+ ions. Ideal plug-flow characterisation of ATR was initially assessed under 3 and 5 Hz oscillations, showing pseudo plug-flow behaviour at the higher rate. Composite flocs were characterised by SEM and size analysis, while dewaterability was also studied by sedimentation and pressure filtration. Aggregate sizes were smaller, but denser and more monodisperse from the ATR than in batch. Composite flocs also gave measured specific cake resistances > 10 × smaller than pure BaSO 4. The higher metal removal performance was achieved using the ATR for Cs+ (95.7%) and Sr2+ (99.9%) at 5 Hz oscillation. A further enhancement for Cs+ removal was achieved by introducing Ba2+ ions into ATR after Na 2 SO 4 addition, achieving > 96% Cs+ and > 99.9% Sr2+ removal. Overall, this study highlights that composite flocs outperform pure BaSO 4 in Cs+ and Sr2+ ion removal while achieving greater dewaterability and filterability. Additionally, we show the ATR effectively intensified the co-precipitation process, potentially reducing plant size and cost, making it a suitable process for modular nuclear cleanup and post-management operations. [Display omitted] [ABSTRACT FROM AUTHOR]