Understanding microbial assembly on seawater reverse osmosis membranes to facilitate evaluation of seawater pretreatment options

Dehwah, Abdullah; Cheng, Hong; Missimer, Thomas M.; Hong, Pei-Ying

dc.contributor.author	Dehwah, Abdullah
dc.contributor.author	Cheng, Hong
dc.contributor.author	Missimer, Thomas M.
dc.contributor.author	Hong, Pei-Ying
dc.date.accessioned	2020-01-13T05:38:44Z
dc.date.available	2020-01-13T05:38:44Z
dc.date.issued	2019
dc.identifier.citation	Dehwah, A. H. A., Cheng, H., Missimer, T. M., & Hong, P.-Y. (2019). Understanding microbial assembly on seawater reverse osmosis membranes to facilitate evaluation of seawater pretreatment options. DESALINATION AND WATER TREATMENT, 170, 1–10. doi:10.5004/dwt.2019.24783
dc.identifier.doi	10.5004/dwt.2019.24783
dc.identifier.uri	http://hdl.handle.net/10754/660980
dc.description.abstract	Membrane biofouling is the primary cause of inefficiency in seawater reverse osmosis desalination. The identification and subsequent removal of causative microorganisms would therefore be beneficial. To achieve this aim, the assembly of microorganisms onto the reverse osmosis membranes was first modeled to reveal a niche-selective process. Specifically, bacterial genera Hyphomonas, Muricauda, Bacillus and Pseudoruegeria were detected in occurrence frequency higher than predicted, and likely play a role in biofouling due to production of exopolymers. Subsequently, four different pretreatment systems, namely ultrafiltration (UF) membranes, intake wells, dual media filtration and cartridge filters (CF), were evaluated for their log removal efficiencies of these four genera. UF outperformed the others in removing the potential biofouling-associated genera, but intake wells achieved a higher log removal of cell densities. Microbial regrowth, as denoted by an increase in cell numbers, was consistently observed within the CF. Using well intakes provides the highest degree of pretreatment in removing total cells in a chemical-free manner, while UF is the next best process to remove bacteria and organic carbon compounds most responsible for membrane biofouling.
dc.description.sponsorship	This study is funded through KAUST Competitive Research Grant URF/1/2982-01-01 awarded to P.-Y.H. The authors thank SAWACO company team, and Eng. Nizar Kammourie, Eng. Najm El-Jafery, Eng. Firas Yaish, Eng. Safwan AL Issa, Mr. Jilly Edisan, Mr. Ronald Llamera, and Mr. Nestro Genterola for access to the facilities and on-site support.
dc.publisher	Desalination Publications
dc.relation.url	https://www.deswater.com/DWT_articles/vol_170_papers/170_2019_1.pdf
dc.rights	Archived with thanks to Desalination and Water Treatment
dc.title	Understanding microbial assembly on seawater reverse osmosis membranes to facilitate evaluation of seawater pretreatment options
dc.type	Article
dc.contributor.department	Biological and Environmental Sciences and Engineering (BESE) Division
dc.contributor.department	Environmental Microbial Safety and Biotechnology Lab
dc.contributor.department	Environmental Science and Engineering Program
dc.contributor.department	Water Desalination and Reuse Research Center (WDRC)
dc.identifier.journal	Desalination and Water Treatment
dc.eprint.version	Publisher's Version/PDF
dc.contributor.institution	Desalination Technologies Research Institute (DTRI), Saline Water Conversion Corporation (SWCC), P.O. Box: 8328, Al-Jubail, 31951, Saudi Arabia
dc.contributor.institution	Emergent Technologies Institute, U.A. Whitaker College of Engineering, Florida Gulf Coast University, 16301 Innovation Lane, Fort Myers, FL, 33913, USA
kaust.person	Dehwah, Abdullah
kaust.person	Cheng, Hong
kaust.person	Hong, Pei-Ying
kaust.grant.number	URF/1/2982-01-01
dc.date.accepted	2019-08-13
refterms.dateFOA	2020-02-15T10:25:31Z
kaust.acknowledged.supportUnit	Competitive Research