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dc.contributor.authorDu, Fengmin
dc.contributor.authorWarsinger, David Elan Martin
dc.contributor.authorUrmi, Tamanna I.
dc.contributor.authorThiel, Gregory Parker
dc.contributor.authorKumar, Amit
dc.contributor.authorLienhard, John H
dc.date.accessioned2019-12-02T21:28:19Z
dc.date.available2019-12-02T21:28:19Z
dc.date.issued2018-04
dc.date.submitted2018-04
dc.identifier.issn0013-936X
dc.identifier.issn1520-5851
dc.identifier.urihttps://hdl.handle.net/1721.1/123096
dc.description.abstractThe ability to increase pH is a crucial need for desalination pretreatment (especially in reverse osmosis) and for other industries, but processes used to raise pH often incur significant emissions and nonrenewable resource use. Alternatively, waste brine from desalination can be used to create sodium hydroxide, via appropriate concentration and purification pretreatment steps, for input into the chlor-alkali process. In this work, an efficient process train (with variations) is developed and modeled for sodium hydroxide production from seawater desalination brine using membrane chlor-alkali electrolysis. The integrated system includes nanofiltration, concentration via evaporation or mechanical vapor compression, chemical softening, further ion-exchange softening, dechlorination, and membrane electrolysis. System productivity, component performance, and energy consumption of the NaOH production process are highlighted, and their dependencies on electrolyzer outlet conditions and brine recirculation are investigated. The analysis of the process also includes assessment of the energy efficiency of major components, estimation of system operating expense and comparison with similar processes. The brine-to-caustic process is shown to be technically feasible while offering several advantages, that is, the reduced environmental impact of desalination through lessened brine discharge, and the increase in the overall water recovery ratio of the reverse osmosis facility. Additionally, best-use conditions are given for producing caustic not only for use within the plant, but also in excess amounts for potential revenue.en_US
dc.publisherAmerican Chemical Society (ACS)en_US
dc.relation.isversionofhttp://dx.doi.org/10.1021/acs.est.8b01195en_US
dc.rightsArticle is made available in accordance with the publisher's policy and may be subject to US copyright law. Please refer to the publisher's site for terms of use.en_US
dc.sourceElizabeth Soergelen_US
dc.titleResource recovery from desalination brine: energy efficiency and purification process integration for sodium hydroxide productionen_US
dc.title.alternativeSodium Hydroxide Production from Seawater Desalination Brine: Process Design and Energy Efficiencyen_US
dc.typeArticleen_US
dc.identifier.citationF. Du et al. “Sodium hydroxide production from seawater desalination brine: process design and energy efficiency,” Environmental Science & Technology, 52, 10 (April 2018): 5949–5958 © 2018 American Chemical Societyen_US
dc.contributor.departmentMassachusetts Institute of Technology. Department of Mechanical Engineeringen_US
dc.contributor.departmentRohsenow Kendall Heat Transfer Laboratory (Massachusetts Institute of Technology)en_US
dc.relation.journalEnvironmental Science & Technologyen_US
dc.eprint.versionAuthor's final manuscripten_US
dc.type.urihttp://purl.org/eprint/type/JournalArticleen_US
eprint.statushttp://purl.org/eprint/status/PeerRevieweden_US
dspace.date.submission2019-06-18T17:20:07Z
mit.journal.volume52en_US
mit.journal.issue10en_US
mit.licenseOPEN_ACCESS_POLICY


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