Brian C. McCool scite author profile

The potential for mineral scaling that may limit the generation of new potable water resources by reverse osmosis (RO), from inland brackish water of high gypsum scaling propensity, was experimentally explored via flux decline measurements and real-time RO membrane surface imaging. Antagonistic gypsum and calcium carbonate scaling kinetics were demonstrated for high-sulfate brackish water desalting. RO scaling studies with brackish water from the California San Joaquin Valley (approximately 10 000 mg/L total dissolved solids) revealed that membrane gypsum scaling was increasingly retarded with rising bicarbonate concentrations. Crystal growth rate, fractional membrane scale coverage, and flux decline decreased by up to about 63, 78, and 73%, respectively, as the bicarbonate concentration increased, at the membrane surface, from < 0.01 to 7.81 mM, for a gypsum saturation index of 2. Inhibition of gypsum crystal growth was attributed to bicarbonate adsorption onto the crystal surfaces, and CaCO3 scaling was undetected even up to a calcite saturation index of approximately 16. Given the suppression of gypsum scaling by bicarbonate, it is essential to considerthis effect in the conventional practice of pH adjustment to suppress CaCO3 scaling. The present results suggest that antagonistic and synergistic mineral crystallization kinetics effects are important for optimizing scale-control strategies (e.g., acid and antiscalants addition to the RO feed).

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Accelerated desupersaturation of reverse osmosis concentrate by chemically-enhanced seeded precipitation

Rahardianto¹,

McCool

Cohen

2010

Desalination

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Feasibility of reverse osmosis desalination of brackish agricultural drainage water in the San Joaquin Valley

McCool

Rahardianto

Faria³

et al. 2010

Desalination

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Membrane Desalination of Agricultural Drainage Water

Cohen

McCool

Rahardianto

et al. 2013

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Antiscalant removal in accelerated desupersaturation of RO concentrate via chemically-enhanced seeded precipitation (CESP)

McCool¹,

Rahardianto²,

Cohen³

2012

Water Research

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Brian C. McCool

Reverse Osmosis Desalting of Inland Brackish Water of High Gypsum Scaling Propensity: Kinetics and Mitigation of Membrane Mineral Scaling

Accelerated desupersaturation of reverse osmosis concentrate by chemically-enhanced seeded precipitation

Feasibility of reverse osmosis desalination of brackish agricultural drainage water in the San Joaquin Valley

Membrane Desalination of Agricultural Drainage Water

Antiscalant removal in accelerated desupersaturation of RO concentrate via chemically-enhanced seeded precipitation (CESP)

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