The Minus Approach Can Redefine the Standard of Practice of Drinking Water Treatment

Reid, Elliot; Igou, Thomas; Zhao, Yangying; Crittenden, John C.; Huang, Ching-Hua; Westerhoff, Paul; Rittmann, Bruce E.; Drewes, Jörg E.; Chen, Yongsheng

doi:10.1021/acs.est.2c09389

Cited by 18 publications

(5 citation statements)

References 140 publications

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“…Nanofiltration (NF) has obtained a variety of applications in the environmental fields, including softening of hard water, − removal of natural organic matter , and emerging contaminants from drinking water, separation of sulfate from chloride for zero liquid discharge, and more recently lithium extraction from natural brines. − In these applications, the requirement for the highly selective separation of some solutes from others could perfectly be satisfied by the rejection characteristics of NF membranes. The membrane properties, however, must be well tuned based on the rejection mechanisms, including steric hindrance effect, electrostatic effects, etc. − Taking the lithium–magnesium separation as an example, if the effective pore size of an NF membrane is in between the sizes of hydrated ions of lithium (0.382 nm) and magnesium (0.428 nm), effective separation of the two types of ions can be achieved by the membrane.…”

Section: Introductionmentioning

confidence: 99%

Simultaneously Modulating Nanofiltration Membrane Surface Charges and Pore Size in Pursuit of Effective Cation Separation via a Bi-Functional Monomers-Interfered IP Reaction

Wang,

Gao,

Zhang

et al. 2024

ACS EST Eng.

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Reducing the membrane surface negative charge density and properly enlarging the pore size could benefit the selective and efficient separation of divalent cations from monovalent cations desired by many applications (e.g., Li + /Mg 2+ separation) using nanofiltration (NF) by synergistically exploiting the Donnan and steric effects. This study provides a one-step tactic for the preparation of such membranes by simply introducing a small percentage of sulfuryl chloride (SO 2 Cl 2 ) into the organic phase of trimesoyl chloride (TMC). This method is adaptable to the classical interfacial polymerization (IP) technique. The key conditions include a sufficient high concentration of piperazine (PIP) in the aqueous phase (e.g., 2.0 wt %) and a low-to-medium concentration ratio of sulfuryl chloride to TMC. An as-prepared membrane, which manifested a high Li + / Mg 2+ selectivity of 22.2, exhibited a high rejection of MgCl 2 at 92%, a low rejection of Na 2 SO 4 at 34%, and a relatively high water permeance of 11.1 L m −2 h −1 bar −1 . We propose that the sulfuryl chloride monomers mainly played an interferential role rather than largely being incorporated into the polyamide matrix. This was demonstrated by the very low sulfur element composition in the active layer and the substantially enlarged membrane pore size in comparison to that of the control membrane. Adding sulfuryl chloride into the organic phase could allow more PIP monomers to diffuse through the enlarged structure to the superficial surface of the membrane, leaving more unreacted amine groups endowed with positive charges. Moreover, the addition of sulfuryl chloride could greatly change the membrane surface and structural morphologies, and in turn the surface roughness, by increasing the number of large ring-like structures and/or rougher nodules that could cover almost the entire membrane surface. Therefore, this work demonstrated that the membranes fabricated by the novel approach could have practical applications for cation separation.

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Section: Introductionmentioning

confidence: 99%

Simultaneously Modulating Nanofiltration Membrane Surface Charges and Pore Size in Pursuit of Effective Cation Separation via a Bi-Functional Monomers-Interfered IP Reaction

Wang,

Gao,

Zhang

et al. 2024

ACS EST Eng.

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“…Despite significant research efforts in the field of DBPs, − the understanding of their formation in chlorinated drinking water remains incomplete. It has been observed that the formation of DBPs is affected by certain environmental parameters such as the interaction with various types of NOM, temperature, and pH.…”

Section: Introductionmentioning

confidence: 99%

Assessing the Health Impact of Disinfection Byproducts in Drinking Water

Kalita,

Kamilaris,

Havinga

et al. 2024

ACS EST Water

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This study provides a comprehensive investigation of the impact of disinfection byproducts (DBPs) on human health, with a particular focus on DBPs present in chlorinated drinking water, concentrating on three primary DBP categories (aliphatic, alicyclic, and aromatic). Additionally, it explores pivotal factors influencing DBP formation, encompassing disinfectant types, water source characteristics, and environmental conditions, such as the presence of natural materials in water. The main objective is to discern the most hazardous DBPs, considering criteria such as regulation standards, potential health impacts, and chemical diversity. It provides a catalog of 63 key DBPs alongside their corresponding parameters. From this set, 28 compounds are meticulously chosen for in-depth analysis based on the above criteria. The findings strive to guide the advancement of water treatment technologies and intelligent sensory systems for the efficient water quality surveillance. This, in turn, enables reliable DBP detection within water distribution networks. By enriching the understanding of DBP-associated health hazards and offering valuable insights, this research is aimed to contribute to influencing policy-making in regulations and treatment strategies, thereby protecting public health and improving safety related to chlorinated drinking water quality.

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“…During oxidative water treatments, dissolved organic matter (DOM) serves as not only the primary sink for the dosed oxidant , but also the primary precursor of DBPs. − Previous studies have shown that changes of DOM characteristics closely correlate with DBP formation, , and the redox-active moieties of DOM compete directly for the oxidant against MPs. − Therefore, monitoring the changes in DOM characteristics induced by oxidation is a feasible way to determine the appropriate oxidant dosage. , Currently, the surrogate indicators commonly employed to optimize the oxidant dosage include the dissolved organic carbon (DOC), UV absorbance at 254 nm (UV 254 ), and fluorescence index (FI). ,,, However, DOC cannot effectively indicate MP abatement and DBP formation due to limited organic mineralization. , In addition, although the spectroscopic surrogate indicators (UV 254 and FI) have been extensively adopted in oxidative water treatments − and correlate well with MP abatement and DBP formation in lab-scale and full-scale experiments, ,,− they just reflect the changes in the chromophoric moieties of DOM. Therefore, it is necessary to develop a new surrogate indicator to enhance the precision, reliability, and robustness of existing control systems for oxidative water treatments.…”

Section: Introductionmentioning

confidence: 99%

Electron Donating Capacity: A Promising Surrogate Indicator for the Optimization of Oxidative Water Treatments

Ji,

Dong,

Wang

et al. 2024

ACS EST Water

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The redox-active moieties of dissolved organic matter (DOM) significantly influence the degradation of pollutants in oxidative water treatments. Because electron donating capacity (EDC) directly probes the redox properties of DOM, it tends to be a promising surrogate indicator to reflect changes in the DOM oxidation state. Given the complexity of applying EDC to optimizing oxidation processes, this review summarizes a history of advances in EDC analytical methods and discusses key factors for the standardization of EDC measurement. The EDC and UV 254 reductions induced by chemical oxidation are summarized to develop tailored water treatment control strategies. In addition, the applicability of EDC to indicate micropollutant abatement and disinfection byproduct formation is evaluated. Oxidative water treatments with chlorine, chlorine dioxide, permanganate, and ferrate yield a more pronounced reduction in EDC than in UV 254 due to the formation of quinone moieties, while ozonation causes a comparatively smaller EDC reduction but a larger UV 254 reduction. For oxidative water treatments in which the oxidant dosage is difficult to predict, EDC could serve as a promising surrogate indicator to meet treatment goals.

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The Minus Approach Can Redefine the Standard of Practice of Drinking Water Treatment

Cited by 18 publications

References 140 publications

Simultaneously Modulating Nanofiltration Membrane Surface Charges and Pore Size in Pursuit of Effective Cation Separation via a Bi-Functional Monomers-Interfered IP Reaction

Simultaneously Modulating Nanofiltration Membrane Surface Charges and Pore Size in Pursuit of Effective Cation Separation via a Bi-Functional Monomers-Interfered IP Reaction

Assessing the Health Impact of Disinfection Byproducts in Drinking Water

Electron Donating Capacity: A Promising Surrogate Indicator for the Optimization of Oxidative Water Treatments

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