Litcius/Paper detail

Removal of cesium and strontium ions with enhanced solid-liquid separation by combined ion exchange and BaSO4 co-precipitation

Oguzhan Kivan, Muhammad Yusuf, David Harbottle, Timothy N. Hunter

2024Journal of Water Process Engineering24 citationsDOIOpen Access PDF

Abstract

Treatment of cesium and strontium is critical in radioactive liquid waste management, where their ions are difficult to remove in single operations, owing to differences in valence state. Here, the efficacy of composite coagulants synthesised by combining fine clinoptilolite with co-precipitated barite (BaSO 4 ) were investigated for the simultaneous removal of Cs + and Sr 2+ ions, producing aggregates with enhanced dewatering properties. Co-precipitated BaSO 4 without clinoptilolite was found to be very effective in the removal of Sr 2+ (>99 %) while only giving low-level Cs + removal (~14 %) for solutions containing 25 ppm of Cs + and Sr 2 . Conversely, pure clinoptilolite gave high Cs + removal (>98 %) with rapid adsorption (<1 h) fitted to a Pseudo-Second Order (PSO) rate model. Composite coagulants were then produced using natural clinoptilolite combined with BaSO 4 co-precipitation. Higher Sr 2+ removal was obtained in all cases (>99.9 %), whereas Cs + removal was reduced to <90 %, owing to exchange interactions with free Ba 2+ ions. However, NaCl-preactivated clinoptilolite overcame low Cs + removal efficiency, achieving >95 % removal. Their physical properties, sedimentation rates, and compressional yield stress were also studied to characterise the aggregates solid-liquid separation behaviour. The combined coagulates obtained settling rates almost twice that of pure BaSO 4 , and produced much greater consolidation, owing to increased aggregate density. Also, the combined systems had a higher gel point and lower specific compressive yield stress, suggesting less resistance to compression under centrifugal forces for dewatering. Overall, this study highlights that the use of composite coagulants can improve the removal efficiency of Cs + and Sr 2+ while also accelerating solid-liquid dewatering. • Core-shell coagulants of clinoptilolite & BaSO 4 for Cs + and Sr 2+ removal. • Combined coagulant removal efficiency was >99.9 % for Sr 2+ and >95 % for Cs + . • Physical properties, settling rates, and compressive yield stress also studied. • Settling rate for the combined system was 2 × BaSO 4 rate with 3 × consolidation. • Increase in combined sediment yield stress at significantly greater bed vol%.

Topics & Concepts

ClinoptiloliteDewateringPrecipitationIon exchangeCoprecipitationAdsorptionChemistryMaterials scienceIonChemical engineeringNuclear chemistryChromatographyZeoliteInorganic chemistryOrganic chemistryGeotechnical engineeringMeteorologyCatalysisPhysicsEngineeringChemical Synthesis and CharacterizationRadioactive element chemistry and processingNuclear materials and radiation effects
Removal of cesium and strontium ions with enhanced solid-liquid separation by combined ion exchange and BaSO4 co-precipitation | Litcius