Fate of steroid hormone micropollutant estradiol in a hybrid magnetic ion exchange resin-nanofiltration process
Alessandra Imbrogno A B , Prantik Samanta A and Andrea I. Schäfer AA Membrane Technology Department, Institute of Functional Interfaces (IFG-MT), Karlsruhe Institute of Technology (KIT), Hermann-von-Helmholtz-Platz 1, 76344 Eggenstein-Leopoldshafen, Germany.
B Corresponding author. Email: alessandra.imbrogno@kit.edu
Environmental Chemistry 16(8) 630-640 https://doi.org/10.1071/EN19126
Submitted: 3 May 2019 Accepted: 12 August 2019 Published: 2 October 2019
Environmental context. Contamination of surface water by micropollutants is a major environmental concern because of their high persistence and toxicity. Micropollutants are only partially removed in nanofiltration water treatment systems, encouraging the investigation of more complex systems involving partitioning with membrane materials, organic matter and ion exchange resins. This study elucidates the micropollutant partitioning mechanisms in this complex water treatment system.
Abstract. The accumulation of micropollutants, such as steroid hormones, in magnetic ion exchange resin-nanofiltration (MIEX-NF) poses a risk to the environmental contamination of surface water where the treated water is discharged. In this study, the partitioning of the steroid hormone estradiol (E2) with humic acid (HA), MIEX and the membrane is investigated at different feed water conditions (e.g. pH and presence of calcium). The transport and adsorption of E2 in NF is not affected significantly by the E2-HA interaction. Indeed, E2 partitions with HA between 8 % and 25 % at different pH. This is attributed to the presence of calcium ions, which reduces the number of HA molecules available to interact with E2 molecules. The calcium interference is evident especially at pH > 10, where calcite and HA precipitate to result in irreversible membrane fouling. In the hybrid MIEX-NF process, the E2-MIEX interaction occurs at all pH conditions. Approximately 40 % of the E2 total mass partitions with MIEX. This is significantly higher than E2 accumulation in NF. Since the partitioning is at least partially reversible, this poses a risk for accidental E2 release into the process streams.
Additional keywords: fouling, humic acid, organic matter, surface water treatment, water reuse.
References
Ang WS, Tiraferri A, Chen KL, Elimelech M (2011). Fouling and cleaning of RO membranes fouled by mixtures of organic foulants simulating wastewater effluent. Journal of Membrane Science 376, 196–206.| Fouling and cleaning of RO membranes fouled by mixtures of organic foulants simulating wastewater effluentCrossref | GoogleScholarGoogle Scholar |
Aryal A, Sathasivan A, Heitz A, Zheng G, Nikraz H, Ginige MP (2015). Combined BAC and MIEX pre-treatment of secondary wastewater effluent to reduce fouling of nanofiltration membranes. Water Research 70, 214–223.
| Combined BAC and MIEX pre-treatment of secondary wastewater effluent to reduce fouling of nanofiltration membranesCrossref | GoogleScholarGoogle Scholar | 25540835PubMed |
Brigante M, Zanini G, Avena M (2007). On the dissolution kinetics of humic acid particles: effects of pH, temperature and Ca2+ concentration. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 294, 64–70.
| On the dissolution kinetics of humic acid particles: effects of pH, temperature and Ca2+ concentrationCrossref | GoogleScholarGoogle Scholar |
Choi K-J, Son H-J, Kim S-H (2007). Ionic treatment for removal of sulfonamide and tetracycline classes of antibiotic. The Science of the Total Environment 387, 247–256.
| Ionic treatment for removal of sulfonamide and tetracycline classes of antibioticCrossref | GoogleScholarGoogle Scholar | 17764725PubMed |
Comerton AM, Andrews RC, Bagley DM, Yang P (2007). Membrane adsorption of endocrine disrupting compounds and pharmaceutically active compounds. Journal of Membrane Science 303, 267–277.
Comerton AM, Andrews RC, Bagley DM, Hao C (2008). The rejection of endocrine disrupting and pharmaceutically active compounds by NF and RO membranes as a function of compound and water matrix properties. Journal of Membrane Science 313, 323–335.
| The rejection of endocrine disrupting and pharmaceutically active compounds by NF and RO membranes as a function of compound and water matrix propertiesCrossref | GoogleScholarGoogle Scholar |
Comerton AM, Andrews RC, Bagley DM (2009). The influence of natural organic matter and cations on the rejection of endocrine disrupting and pharmaceutically active compounds by nanofiltration. Water Research 43, 613–622.
| The influence of natural organic matter and cations on the rejection of endocrine disrupting and pharmaceutically active compounds by nanofiltrationCrossref | GoogleScholarGoogle Scholar | 19046596PubMed |
Daughton CG, Ternes TA (1999). Pharmaceuticals and personal care products in the environment: agents of subtle change?. Environmental Health Perspectives 107, 907–938.
Gude VG (2017). Desalination and water reuse to address global water scarcity. Reviews in Environmental Science and Bio/Technology 16, 591–609.
| Desalination and water reuse to address global water scarcityCrossref | GoogleScholarGoogle Scholar |
Hong S, Elimelech M (1997). Chemical and physical aspects of natural organic matter (NOM) fouling of nanofiltration membranes. Journal of Membrane Science 132, 159–181.
| Chemical and physical aspects of natural organic matter (NOM) fouling of nanofiltration membranesCrossref | GoogleScholarGoogle Scholar |
Hu J, Jin X, Ong S (2007). Rejection of estrone by nanofiltration: Influence of solution chemistry. Journal of Membrane Science 302, 188–196.
| Rejection of estrone by nanofiltration: Influence of solution chemistryCrossref | GoogleScholarGoogle Scholar |
Huerta-Fontela M, Galceran MT, Ventura F (2011). Occurrence and removal of pharmaceuticals and hormones through drinking water treatment. Water Research 45, 1432–1442.
| Occurrence and removal of pharmaceuticals and hormones through drinking water treatmentCrossref | GoogleScholarGoogle Scholar | 21122885PubMed |
Imbrogno A, Biscarat J, Schäfer AI (2017). Estradiol Uptake in a Combined Magnetic Ion Exchange – Ultrafiltration (MIEX-UF) Process During Water Treatment. Current Pharmaceutical Design 23, 328–337.
Imbrogno A, Tiraferri A, Abbenante S, Weyand S, Schwaiger R, Luxbacher T, Schäfer AI (2018). Organic fouling control through magnetic ion exchange‐nanofiltration (MIEX‐NF) in water treatment. Journal of Membrane Science 549, 474–485.
| Organic fouling control through magnetic ion exchange‐nanofiltration (MIEX‐NF) in water treatmentCrossref | GoogleScholarGoogle Scholar |
Jin X, Hu J, Ong SL (2010). Removal of natural hormone estrone from secondary effluents using nanofiltration and reverse osmosis. Water Research 44, 638–648.
| Removal of natural hormone estrone from secondary effluents using nanofiltration and reverse osmosisCrossref | GoogleScholarGoogle Scholar | 19879623PubMed |
Jones O, Voulvoulis N, Lester J (2006). Partitioning behavior of five pharmaceutical compounds to activated sludge and river sediment. Archives of Environmental Contamination and Toxicology 50, 297–305.
| Partitioning behavior of five pharmaceutical compounds to activated sludge and river sedimentCrossref | GoogleScholarGoogle Scholar | 16328615PubMed |
Joo SH, Tansel B (2015). Novel technologies for reverse osmosis concentrate treatment: a review. Journal of Environmental Management 150, 322–335.
| Novel technologies for reverse osmosis concentrate treatment: a reviewCrossref | GoogleScholarGoogle Scholar | 25528173PubMed |
Kaewsuk J, Seo GT (2011). Verification of NOM removal in MIEX-NF system for advanced water treatment. Separation and Purification Technology 80, 11–19.
| Verification of NOM removal in MIEX-NF system for advanced water treatmentCrossref | GoogleScholarGoogle Scholar |
Kell GS (1975). Density, thermal expansivity, and compressibility of liquid water from 0. deg. to 150. deg. Correlations and tables for atmospheric pressure and saturation reviewed and expressed on 1968 temperature scale. Journal of Chemical & Engineering Data 20, 97–105.
| Density, thermal expansivity, and compressibility of liquid water from 0. deg. to 150. deg. Correlations and tables for atmospheric pressure and saturation reviewed and expressed on 1968 temperature scaleCrossref | GoogleScholarGoogle Scholar |
Khanal SK, Xie B, Thompson ML, Sung S, Ong S-K, van Leeuwen J (2006). Fate, Transport, and Biodegradation of Natural Estrogens in the Environment and Engineered Systems. Environmental Science & Technology 40, 6537–6546.
| Fate, Transport, and Biodegradation of Natural Estrogens in the Environment and Engineered SystemsCrossref | GoogleScholarGoogle Scholar |
Koyuncu I, Arikan OA, Wiesner MR, Rice C (2008). Removal of hormones and antibiotics by nanofiltration membranes. Journal of Membrane Science 309, 94–101.
| Removal of hormones and antibiotics by nanofiltration membranesCrossref | GoogleScholarGoogle Scholar |
Krop HB, van Noort PC, Govers HA (2001). Determination and theoretical aspects of the equilibrium between dissolved organic matter and hydrophobic organic micropollutants in water (Kdoc). In ‘Reviews of environmental contamination and toxicology’. (Ed. GW Ware) Vol. 169, pp. 1–122. (Springer: New York, NY)
Kummu M, Guillaume J, de Moel H, Eisner S, Flörke M, Porkka M, Siebert S, Veldkamp TI, Ward PJ (2016). The world’s road to water scarcity: shortage and stress in the 20th century and pathways towards sustainability. Scientific Reports 6, 38495
| The world’s road to water scarcity: shortage and stress in the 20th century and pathways towards sustainabilityCrossref | GoogleScholarGoogle Scholar | 27934888PubMed |
Lewis K, Archer R (1979). pKa values of estrone, 17β-estradiol and 2-methoxyestrone. Steroids 34, 485–499.
| pKa values of estrone, 17β-estradiol and 2-methoxyestroneCrossref | GoogleScholarGoogle Scholar | 516114PubMed |
Liu Y-l, Wang X-m, Yang H-w, Xie YF (2018). Adsorption of pharmaceuticals onto isolated polyamide active layer of NF/RO membranes. Chemosphere 200, 36–47.
| Adsorption of pharmaceuticals onto isolated polyamide active layer of NF/RO membranesCrossref | GoogleScholarGoogle Scholar | 29471167PubMed |
López-Ortiz C, Sentana-Gadea I, Varó-Galvañ PJ, Maestre-Pérez S, Prats-Rico D (2018a). Effect of magnetic ion exchange (MIEX®) on removal of emerging organic contaminants. Chemosphere 208, 433–440.
| Effect of magnetic ion exchange (MIEX®) on removal of emerging organic contaminantsCrossref | GoogleScholarGoogle Scholar | 29885510PubMed |
López-Ortiz CM, Sentana-Gadea I, Varó-Galvañ P, Maestre-Pérez SE, Prats-Rico D (2018b). The use of combined treatments for reducing parabens in surface waters: Ion-exchange resin and nanofiltration. The Science of the Total Environment 639, 228–236.
| The use of combined treatments for reducing parabens in surface waters: Ion-exchange resin and nanofiltrationCrossref | GoogleScholarGoogle Scholar | 29787906PubMed |
Luo Y, Guo W, Ngo HH, Nghiem LD, Hai FI, Zhang J, Liang S, Wang XC (2014). A review on the occurrence of micropollutants in the aquatic environment and their fate and removal during wastewater treatment. The Science of the Total Environment 473–474, 619–641.
| A review on the occurrence of micropollutants in the aquatic environment and their fate and removal during wastewater treatmentCrossref | GoogleScholarGoogle Scholar | 24394371PubMed |
Mailler R, Gasperi J, Coquet Y, Deshayes S, Zedek S, Cren-Olivé C, Cartiser N, Eudes V, Bressy A, Caupos E (2015). Study of a large scale powdered activated carbon pilot: Removals of a wide range of emerging and priority micropollutants from wastewater treatment plant effluents. Water Research 72, 315–330.
| Study of a large scale powdered activated carbon pilot: Removals of a wide range of emerging and priority micropollutants from wastewater treatment plant effluentsCrossref | GoogleScholarGoogle Scholar | 25466636PubMed |
Mänttäri M, Pihlajamäki A, Nyström M (2006). Effect of pH on hydrophilicity and charge and their effect on the filtration efficiency of NF membranes at different pH. Journal of Membrane Science 280, 311–320.
| Effect of pH on hydrophilicity and charge and their effect on the filtration efficiency of NF membranes at different pHCrossref | GoogleScholarGoogle Scholar |
McCallum EA, Hyung H, Do TA, Huang C-H, Kim J-H (2008). Adsorption, desorption, and steady-state removal of 17β-estradiol by nanofiltration membranes. Journal of Membrane Science 319, 38–43.
| Adsorption, desorption, and steady-state removal of 17β-estradiol by nanofiltration membranesCrossref | GoogleScholarGoogle Scholar |
Mekonnen MM, Hoekstra AY (2016). Four billion people facing severe water scarcity. Science Advances 2, e1500–323.
| Four billion people facing severe water scarcityCrossref | GoogleScholarGoogle Scholar |
Neale PA, Escher BI, Schäfer AI (2008). Quantification of solute–solute interactions using negligible-depletion solid-phase microextraction: measuring the affinity of estradiol to bulk organic matter. Environmental Science & Technology 42, 2886–2892.
| Quantification of solute–solute interactions using negligible-depletion solid-phase microextraction: measuring the affinity of estradiol to bulk organic matterCrossref | GoogleScholarGoogle Scholar |
Neale PA, Escher BI, Schäfer AI (2009). pH dependence of steroid hormone—organic matter interactions at environmental concentrations. The Science of the Total Environment 407, 1164–1173.
| pH dependence of steroid hormone—organic matter interactions at environmental concentrationsCrossref | GoogleScholarGoogle Scholar | 18977018PubMed |
Neale PA, Mastrup M, Borgmann T, Schäfer AI (2010). Sorption of micropollutant estrone to a water treatment ion exchange resin. Journal of Environmental Monitoring 12, 311–317.
| Sorption of micropollutant estrone to a water treatment ion exchange resinCrossref | GoogleScholarGoogle Scholar | 20082027PubMed |
Nghiem LD, Fujioka T (2016). Removal of emerging contaminants for water reuse by membrane technology. In ‘Emerging membrane technology for sustainable water treatment’. (Eds NP Hankins, R Singh) pp. 217–247. (Elsevier: Amsterdam)
Nghiem LD, Hawkes S (2007). Effects of membrane fouling on the nanofiltration of pharmaceutically active compounds (PhACs): mechanisms and role of membrane pore size. Separation and Purification Technology 57, 176–184.
| Effects of membrane fouling on the nanofiltration of pharmaceutically active compounds (PhACs): mechanisms and role of membrane pore sizeCrossref | GoogleScholarGoogle Scholar |
Nghiem L, Schäfer AI (2002). Adsorption and transport of trace contaminant estrone in NF/RO membranes. Environmental Engineering Science 19, 441–451.
| Adsorption and transport of trace contaminant estrone in NF/RO membranesCrossref | GoogleScholarGoogle Scholar |
Nghiem LD, Schäfer AI (2006). Critical risk points of nanofiltration and reverse osmosis processes in water recycling applications. Desalination 187, 303–312.
| Critical risk points of nanofiltration and reverse osmosis processes in water recycling applicationsCrossref | GoogleScholarGoogle Scholar |
Nghiem L, Schäfer AI, Waite T (2002). Adsorptive interactions between membranes and trace contaminants. Desalination 147, 269–274.
| Adsorptive interactions between membranes and trace contaminantsCrossref | GoogleScholarGoogle Scholar |
Nghiem L, McCutcheon J, Schäfer AI, Elimelech M (2004). The role of endocrine disrupters in water recycling: risk or mania?. Water Science and Technology 50, 215–220.
| The role of endocrine disrupters in water recycling: risk or mania?Crossref | GoogleScholarGoogle Scholar | 15344794PubMed |
Nghiem LD, Coleman PJ, Espendiller C (2010). Mechanisms underlying the effects of membrane fouling on the nanofiltration of trace organic contaminants. Desalination 250, 682–687.
| Mechanisms underlying the effects of membrane fouling on the nanofiltration of trace organic contaminantsCrossref | GoogleScholarGoogle Scholar |
Ouatmane A, Hafidi M, Gharous ME, Revel J (1999). Complexation of calcium ions by humic and fulvic acids. Analusis 27, 428–431.
| Complexation of calcium ions by humic and fulvic acidsCrossref | GoogleScholarGoogle Scholar |
Pal A, Gin KY-H, Lin AY-C, Reinhard M (2010). Impacts of emerging organic contaminants on freshwater resources: review of recent occurrences, sources, fate and effects. The Science of the Total Environment 408, 6062–6069.
| Impacts of emerging organic contaminants on freshwater resources: review of recent occurrences, sources, fate and effectsCrossref | GoogleScholarGoogle Scholar | 20934204PubMed |
Pandey AK, Pandey SD, Misra V (2000). Stability constants of metal–humic acid complexes and its role in environmental detoxification. Ecotoxicology and Environmental Safety 47, 195–200.
| Stability constants of metal–humic acid complexes and its role in environmental detoxificationCrossref | GoogleScholarGoogle Scholar | 11023698PubMed |
Perrin DD, Dempsey B, Serjeant EP (1981). ‘pKa prediction for organic acids and bases.’ (Springer: New York, NY)
Petrie B, Barden R, Kasprzyk-Hordern B (2015). A review on emerging contaminants in wastewaters and the environment: current knowledge, understudied areas and recommendations for future monitoring. Water Research 72, 3–27.
| A review on emerging contaminants in wastewaters and the environment: current knowledge, understudied areas and recommendations for future monitoringCrossref | GoogleScholarGoogle Scholar | 25267363PubMed |
Sadmani AA, Andrews RC, Bagley DM (2014a). Impact of natural water colloids and cations on the rejection of pharmaceutically active and endocrine disrupting compounds by nanofiltration. Journal of Membrane Science 450, 272–281.
| Impact of natural water colloids and cations on the rejection of pharmaceutically active and endocrine disrupting compounds by nanofiltrationCrossref | GoogleScholarGoogle Scholar |
Sadmani AA, Andrews RC, Bagley DM (2014b). Nanofiltration of pharmaceutically active and endocrine disrupting compounds as a function of compound interactions with DOM fractions and cations in natural water. Separation and Purification Technology 122, 462–471.
| Nanofiltration of pharmaceutically active and endocrine disrupting compounds as a function of compound interactions with DOM fractions and cations in natural waterCrossref | GoogleScholarGoogle Scholar |
Schäfer AI, Fane AG, Waite TD (1998). Nanofiltration of natural organic matter: Removal, fouling and the influence of multivalent ions. Desalination 118, 109–122.
| Nanofiltration of natural organic matter: Removal, fouling and the influence of multivalent ionsCrossref | GoogleScholarGoogle Scholar |
Schäfer AI, Nghiem L, Waite T (2003). Removal of the natural hormone estrone from aqueous solutions using nanofiltration and reverse osmosis. Environmental Science & Technology 37, 182–188.
| Removal of the natural hormone estrone from aqueous solutions using nanofiltration and reverse osmosisCrossref | GoogleScholarGoogle Scholar |
Schäfer AI, Nghiem LD, Meier A, Neale PA (2010). Impact of organic matrix compounds on the retention of steroid hormone estrone by a ‘loose’ nanofiltration membrane. Separation and Purification Technology 73, 179–187.
| Impact of organic matrix compounds on the retention of steroid hormone estrone by a ‘loose’ nanofiltration membraneCrossref | GoogleScholarGoogle Scholar |
Schäfer AI, Akanyeti I, Semião AJ (2011). Micropollutant sorption to membrane polymers: a review of mechanisms for estrogens. Advances in Colloid and Interface Science 164, 100–117.
| Micropollutant sorption to membrane polymers: a review of mechanisms for estrogensCrossref | GoogleScholarGoogle Scholar | 21106187PubMed |
Schmidt TC (2018). Recent trends in water analysis triggering future monitoring of organic micropollutants. Analytical and Bioanalytical Chemistry 410, 3933–3941.
| Recent trends in water analysis triggering future monitoring of organic micropollutantsCrossref | GoogleScholarGoogle Scholar | 29564501PubMed |
Schröder P, Helmreich B, Škrbić B, Carballa M, Papa M, Pastore C, Emre Z, Oehmen A, Langenhoff A, Molinos M (2016). Status of hormones and painkillers in wastewater effluents across several European states – considerations for the EU watch list concerning estradiols and diclofenac. Environmental Science and Pollution Research International 23, 12835–12866.
| Status of hormones and painkillers in wastewater effluents across several European states – considerations for the EU watch list concerning estradiols and diclofenacCrossref | GoogleScholarGoogle Scholar | 27023823PubMed |
Schwarzenbach RP, Escher BI, Fenner K, Hofstetter TB, Johnson CA, Von Gunten U, Wehrli B (2006). The challenge of micropollutants in aquatic systems. Science 313, 1072–1077.
| The challenge of micropollutants in aquatic systemsCrossref | GoogleScholarGoogle Scholar | 16931750PubMed |
Seidel A, Elimelech M (2002). Coupling between chemical and physical interactions in natural organic matter (NOM) fouling of nanofiltration membranes: implications for fouling control. Journal of Membrane Science 203, 245–255.
| Coupling between chemical and physical interactions in natural organic matter (NOM) fouling of nanofiltration membranes: implications for fouling controlCrossref | GoogleScholarGoogle Scholar |
Semião AJ, Schäfer AI (2013). Removal of adsorbing estrogenic micropollutants by nanofiltration membranes. Part A – Experimental evidence. Journal of Membrane Science 431, 244–256.
| Removal of adsorbing estrogenic micropollutants by nanofiltration membranes. Part A – Experimental evidenceCrossref | GoogleScholarGoogle Scholar |
Shen J, Jin Yang X, Schäfer AI (2012). Quantification of hormone–humic acid interactions in nanofiltration. Environmental Science & Technology 46, 10597–10604.
| Quantification of hormone–humic acid interactions in nanofiltrationCrossref | GoogleScholarGoogle Scholar |
Tagliavini M, Engel F, Weidler PG, Scherer T, Schäfer AI (2017). Adsorption of steroid micropollutants on polymer-based spherical activated carbon (PBSAC). Journal of Hazardous Materials 337, 126–137.
| Adsorption of steroid micropollutants on polymer-based spherical activated carbon (PBSAC)Crossref | GoogleScholarGoogle Scholar | 28549305PubMed |
Tang CY, Yang Z, Guo H, Wen JJ, Nghiem LD, Cornelissen E (2018). Potable water reuse through advanced membrane technology. Environmental Science and Technology 52, 10215–10223.
| Potable water reuse through advanced membrane technologyCrossref | GoogleScholarGoogle Scholar | 30137968PubMed |
Tipping E, Hurley MA (1992). A unifying model of cation binding by humic substances. Geochimica et Cosmochimica Acta 56, 3627–3641.
| A unifying model of cation binding by humic substancesCrossref | GoogleScholarGoogle Scholar |
Tran NH, Reinhard M, Gin KY-H (2018). Occurrence and fate of emerging contaminants in municipal wastewater treatment plants from different geographical regions – a review. Water Research 133, 182–207.
| Occurrence and fate of emerging contaminants in municipal wastewater treatment plants from different geographical regions – a reviewCrossref | GoogleScholarGoogle Scholar | 29407700PubMed |
Tran NH, Reinhard M, Khan E, Chen H, Nguyen VT, Li Y, Goh SG, Nguyen QB, Saeidi N, Gin KY-H (2019). Emerging contaminants in wastewater, stormwater runoff, and surface water: Application as chemical markers for diffuse sources. The Science of the Total Environment 676, 252–267.
| Emerging contaminants in wastewater, stormwater runoff, and surface water: Application as chemical markers for diffuse sourcesCrossref | GoogleScholarGoogle Scholar | 31048157PubMed |
Verliefde AR, Cornelissen E, Heijman S, Verberk J, Amy G, Van der Bruggen B, Van Dijk J (2008). The role of electrostatic interactions on the rejection of organic solutes in aqueous solutions with nanofiltration. Journal of Membrane Science 322, 52–66.
| The role of electrostatic interactions on the rejection of organic solutes in aqueous solutions with nanofiltrationCrossref | GoogleScholarGoogle Scholar |
Wang T, Pan X, Ben W, Wang J, Hou P, Qiang Z (2017a). Adsorptive removal of antibiotics from water using magnetic ion exchange resin. Journal of Environmental Sciences 52, 111–117.
| Adsorptive removal of antibiotics from water using magnetic ion exchange resinCrossref | GoogleScholarGoogle Scholar |
Wang T, Yen Y-J, Hsieh Y-K, Wang J (2017b). Size effect of calcium-humic acid non-rigid complexes on the fouling behaviors in nanofiltration: An LA-ICP-MS study. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 513, 335–347.
| Size effect of calcium-humic acid non-rigid complexes on the fouling behaviors in nanofiltration: An LA-ICP-MS studyCrossref | GoogleScholarGoogle Scholar |
Warsinger DM, Chakraborty S, Tow EW, Plumlee MH, Bellona C, Loutatidou S, Karimi L, Mikelonis AM, Achilli A, Ghassemi A (2018). A review of polymeric membranes and processes for potable water reuse. Progress in Polymer Science 81, 209–237.
| A review of polymeric membranes and processes for potable water reuseCrossref | GoogleScholarGoogle Scholar |
Yang Y, Ok YS, Kim K-H, Kwon EE, Tsang YF (2017). Occurrences and removal of pharmaceuticals and personal care products (PPCPs) in drinking water and water/sewage treatment plants: A review. The Science of the Total Environment 596–597, 303–320.
| Occurrences and removal of pharmaceuticals and personal care products (PPCPs) in drinking water and water/sewage treatment plants: A reviewCrossref | GoogleScholarGoogle Scholar | 28437649PubMed |
Zhang R, Vigneswaran S, Ngo H, Nguyen H (2008). Fluidized bed magnetic ion exchange (MIEX®) as pre-treatment process for a submerged membrane reactor in wastewater treatment and reuse. Desalination 227, 85–93.
| Fluidized bed magnetic ion exchange (MIEX®) as pre-treatment process for a submerged membrane reactor in wastewater treatment and reuseCrossref | GoogleScholarGoogle Scholar |