The removal efficiency and reaction mechanism of the aluminum coagulant on phenolic compounds in the presence of hardness salts

Hecini, Lynda; Boukerker, Hassen; Kherifi, Wahida; Mellah, Abdelkarim; Achour, Samia

doi:10.24425/jwld.2022.141576

Artykuł - szczegóły

Tytuł artykułu

The removal efficiency and reaction mechanism of the aluminum coagulant on phenolic compounds in the presence of hardness salts

Autorzy

Hecini Lynda , Boukerker Hassen , Kherifi Wahida , Mellah Abdelkarim , Achour Samia

Treść / Zawartość

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Identyfikatory

DOI

10.24425/jwld.2022.141576

Warianty tytułu

Języki publikacji

Abstrakty

This study is the evaluation of the coagulation efficiency of the aluminum sulfate on the removal of catechol and pyrogallol. The study has focused on the impact of inorganic components of hardness Algerian waters. Jar-test trials were conducted on the two phenolic compounds dissolved in distilled water only, which was later enriched with minerals. Several reaction parameters varied, including the effect of pH and the influence of the salt content, and this approach yielded a better understanding of interaction between phenolic compounds and calcium/magnesium salts. The results indicate that the process efficiency depends on the number and position of OH in molecules. The main mechanisms would be either a physical adsorption, an exchange of ligand, or complexation on the floc surface of aluminum hydroxide. Moreover, the addition of inorganic salts appears to improve removal efficiency of tested phenolic compounds and have an effect on the optimal pH range for coagulation.

Słowa kluczowe

phenolic compounds hardness salt aluminum sulphate coagulation-flocculation mechanism

Wydawca

Wydawnictwo ITP

Czasopismo

Journal of Water and Land Development

Rocznik

2022

Tom

no. 54

Strony

225--233

Opis fizyczny

Bibliogr. 45 poz., fot., tab., wykr.

Twórcy

autor

Hecini Lynda

Scientific and Technical Research Center for Arid Areas (CRSTRA), M.B. 1682 Biskra 07000, Algeria

https://orcid.org/0000-0002-4762-7885

autor

Boukerker Hassen

University of Biskra, Laboratory in Underground and Surface Hydraulics (LARHYSS), Faculty of Science and Technology, Department of Civil Engineering and Hydraulics, Biskra, Algeria

https://orcid.org/0000-0001-8936-4780

autor

Kherifi Wahida

wahidakherifi@yahoo.fr

Scientific and Technical Research Center for Arid Areas (CRSTRA), M.B. 1682 Biskra 07000, Algeria

https://orcid.org/0000-0001-7435-0765

autor

Mellah Abdelkarim

Scientific and Technical Research Center for Arid Areas (CRSTRA), M.B. 1682 Biskra 07000, Algeria

https://orcid.org/0000-0002-6665-8441

autor

Achour Samia

University of Biskra, Laboratory in Underground and Surface Hydraulics (LARHYSS), Faculty of Science and Technology, Department of Civil Engineering and Hydraulics, Biskra, Algeria

https://orcid.org/0000-0003-4767-0960

Bibliografia

ACHOUR S. 2001. Effect of chlorination processes, flocculation and adsorption on the evolution of organic and inorganic compounds in natural waters. PhD Thesis. Tizi-Ouzou University pp. 150.
ACHOUR S., GUESBAYA N. 2005. Coagulation-flocculation by aluminium sulfate of phenolic organic compounds and humic substances. Larhyss Journal. No. 4 p. 153–168.
ACHOUR S., GUESBAYA N. 2006. Tests for flocculation of humic substances in aqueous mineralized media. Larhyss Journal. No. 5 p. 171–178.
AFOUFOU F., ACHOUR S. 2002. Effect of potassium permanganate preoxidation on the elimination of humic substances by flocculation. Courrier du Savoir. No. 2 p. 41–46.
ANKU W.W., MAMO M.A., GOVENDER P.P., 2017. Phenolic compounds in water: Sources, reactivity, toxicity and treatment methods. Chapter 17. In: Phenolic compounds – Natural sources, importance and applications. Eds. M. Soto-Hernandez, M. Palma-Tenango, M. Garcia-Mateos. London. InTechOpen. DOI 10.5772/66927.
BACHA N., ACHOUR S. 2013. Influence of reaction parameters on the stoichiometry of aluminum sulfate/pyromellitic acid in distilled water. Larhyss Journal. No. 13 p. 109–123.
BACHA N., ACHOUR S. 2017. Essais de coagulation de l’acide pyromellitique en milieux aqueux minéralisés [Trials of pyromellitic acid coagulation in media with various degree of mineralization]. Journal of Water and Environmental Sciences. Vol. 1. No sp. ICWR 2 p. 235–242.
BERNHARDT H., HOYER O., LUSSE B. 1986. The addition of calcium to reduce the impairment of flocculation by algogenic organic matter. Zeitschrift für Wasser und Abwasser Forschung. Vol. 19 p. 219–228.
BOUCHAHM N., HECIN L., KHERIFI W. 2016. Softening of groundwater in the eastern region of the Northern Algeria Sahara: Case of the Biskra region. Water Science Journal. Vol. 29(1) p. 37–48. DOI 10.7202/1035715ar.
BOUCHEMAL F., BOUCHAHM N., ACHOUR S. 2011. Quality of waters of aquifer webs of Biskra Region. Journal of Fundamental and Applied Sciences. Vol. 3(1) p. 35–46. DOI 10.4314/jfas.v3i1.4.
BRUCE R.M., SANTODONATO J., NEAL M.W. 1987. Summary review of the health effects associated with phenol. Toxicology and Industrial Health. Vol. 3 p. 535–568.
CAMPANELLA L., BEONE T., SAMMARTINO M., TOMASSETTI M. 1993. Determination of phenol in wastes and water using an enzyme sensor. Analyst. Vol. 118 p. 979–986.
CLEMENT M., SEUX R., MOUSSA B. 1983. Etude des facteurs déterminant la fuite en aluminium dans des eaux d’alimentation préparées à partir d’eaux clarifiées par des sels de ce métal [Studies of the factors determining the leak aluminium in drinking waters prepared from clarified water with salts of this metal]. Tribune du Cebedeau. Vol. 480. No. 336 p. 469–481.
CROUE J. P., VIOLLEAU D., BODAIRE C., LEGUBE B. 1999. Elimination of hydrophobic and hydrophilic constituents by anion exchange resin. Water Science and Technology. Vol. 40 p. 207–214.
Degrémont 2005. Memento technique de l’eau [Technical memento of water]. 10th ed. Paris. France pp. 1718.
DIXON R.A., PAIVA N.L. 1995. Stress induced phenylpropanoid metabolism. The Plant Cell. Vol. 7 p. 1085–1097.
DOMANY Z., GALAMBOS I., VATAI G., MOLNAR E. 2002. Humic substances elimination from drinking water by membrane filtration. Desalination. Vol. 145 p. 333–337.
ERYILMAZA C., GENÇA A. 2021. Review of technologies for the removal of phenol from wastewaters. Journal of Water Chemistry and Technology. Vol. 43. No. 2 p. 145–154. DOI 10.3103/S1063455X21020065.
JECKEL M. 1986. Interactions of humic acids and aluminum salts in flocculation process. Water Research. Vol. 20(12) p. 1535–1542. DOI 10.1016/0043-1354(86)90118-1.
JULIEN F., GUEROUX B., MAZET M. 1994. Comparaison de l’elimination de molecules organiques par coagulation-floculation et par adsorption sur flocs d’hydroxyde metallique preformes [Comparison of the elimination of organic molecules by coagulation-flocculation and by adsorption on preformed metal hydroxide flocs]. Water Research. Vol. 28(12) p. 2567–2574. DOI 10.1016/0043-1354(94)90075-2.
GUESBAYA N. 1998. Elimination des composés organiques par le procédé de coagulation-floculation [Elimination of organic compounds by the coagulation-flocculation process]. MSc Thesis. University of Biskra pp. 178.
HECINI L., ACHOUR S. 2013. Effet de la mineralisation calcique et magnesienne sur l’elimination de composes phenoliques trihydroxyles par coagulation-floculation au sulfate d’aluminium [Effect of calcium and magnesium mineralisation on the elimination of compounds phenolic trihydroxyles by coagulation-flocculation with aluminium sulphate]. 2 nd Conference International “Integrated Management of Water Resources; GIRE’2013”. 22-23.10.2013. Batna University. Algeria.
HECINI L., ACHOUR S. 2014. Coagulation-floculation au sulfate d’aluminium de composés organiques phénoliques et effet de sels de calcium et de magnésium [Coagulation-flocculation by aluminum sulfate of organic phenolic compounds and effect of calcium and magnesium salts]. Revue des Sciences de l’Eau. Vol. 27(3) p. 271–280. DOI 10.7202/1027810ar.
HECINI L., ACHOUR S. 2017. Tests and mechanisms for flocculation of phenylalanine and catechol in the presence of aluminum sulfate. Larhyss Journal. No. 29 p. 341–354.
HECINI L., ACHOUR S. 2018. Incidence of calcic, sulfates and phosfates salts on the coagulation-floculation of organic compounds by aluminium sulfate. International Journal of Engineering Research in Africa. Vol. 34 p. 59–69. DOI 10.4028/www.scientific.net/JERA.34.59.
HUMBERT H., GALLARD H., SUTY H., CROUE J.P. 2008. Natural organic matter (NOM) and pesticides elimination using a combination of ion exchange resin and powdered activated carbon (PAC). Water Research. Vol. 42 p. 1635–1643. DOI 10.1016/j.watres .2007.10.012.
IGNAT I., VOLF I., POPA V.I. 2011. A critical review of methods for characterisation of poly-phenolic compounds in fruits and vegetables. Food Chemistry. Vol. 126(4) p. 1821–1835. DOI 10.1016/j.foodchem.2010.12.026.
JIANG B., SHI S.N., SONG L., TAN L., LI M.D., LIU J.X., XUE L.L. 2016. Efficient treatment of phenolic wastewater with high salinity using a novel integrated system of magnetically immobilized cells coupling with electrodes. Bioresource Technology. Vol. 218 p. 108–114. DOI 10.1016/j.biortech.2016.06.080.
KHERIFI W., HECINI L., BEKIRI F., KHERICI-BOUSNOUBRA H. 2019. Faecal contamination of water in the Lake Mellah and its catchment area, north-eastern Algeria. Journal of Water and Land Development. No. 42 p. 110–116. DOI 10.2478/jwld-2019-0051.
KULKARNI S.J., KAWARE D.J.P. 2013. Review on research for removal of phenol from waste water. International Journal of Scientific and Research Publications. Vol. 3 p. 1–4.
LEFEBVRE E. 1990. Coagulation of aquatic humic substances by ferric iron in aqueous environment. Effect of preoxidation. PhD Thesis. Poitiers University pp. 165.
LEFEBVRE E., LEGUBE B. 1993. Coagulation-flocculation by ferric chloride of some acids and phenols in aqueous solution. Water Research. Vol. 27. No. 3 p. 433–447.
RAHNI M. 1994. Coagulation-flocculation of some organic compounds by ferrous iron in aqueous medium: Study of mechanism and comparison with adsorption. PhD Thesis. University of Poitiers, France pp. 200.
RAKOTONAVIRO E., TONDRE C., BOTTERO J.Y., MALLEVIALLE J. 1989. Complexation of aluminum (III) polymerise et hydrolyse with ions salicylates. Water Research. Vol. 23. No. 9 p. 1137–1145.
REZEG A. 2004. Elimination d’acides organiques hydroxylés et carboxylés par coagulation-floculation au sulfate d’aluminium [Elimination of hydroxylated and carboxylated organic acids by coagulation-flocculation with aluminum sulfate]. MSc Thesis. Biskra University pp. 120.
REZEG A. 2010. Etude des mécanismes d’élimination de la matière organique par un procédé combiné floculation-adsorption en présence de sels et d’oxydes métalliques [Study of the mechanisms of elimination of organic matter by a combined flocculation-adsorption process in the presence of metal oxides and salts]. PhD Thesis. University of Biskra pp. 100.
REZEG A., ACHOUR S. 2005. Elimination d’acides organiques aromatiques par coagulation-floculation au sulfate d’aluminium [Elimination of aromatic organic acids by coagulation-flocculation with aluminum sulfate]. Larhyss Journal. No. 4 p. 141–152.
RODIER J., LEGUBE B., MERLET N., BRUNET R. 2009. Water analysis. Natural waters, wastewater, seawater. 9 th ed. Paris. Dunod pp. 1384.
SEDRATI N. 2011. Origines et caractéristiques physico-chimiques des eaux de la wilaya de Biskra-Sud Est Algerien [Origins and physicochemical characteristics of the waters of the wilaya of Biskra South-East Algeria]. PhD Thesis. Annaba, Algeria. Badji Mokhtar University pp. 252.
SEMMENS M. J., AYERS K. 1985. Removal by coagulation of trace organics from Mississippi River. Journal AWWA. Vol. 77(5) p. 79–84.
SURESH S., SRIVASTAVA V.C., MISHRA I.M. 2012. Adsorption of catechol, resorcinol, hydroquinone, and their derivatives: A review. International Journal of Energy and Environmental Engineering. Vol. 3, 32. DOI 10.1186/2251-6832-3-32.
UPADHYAY G., SATYA P., OM PRAKASH G. MAHENDRA P.S. 2010. Pyrogallol-mediated toxicity and natural antioxidants: Triumphs and pitfalls of preclinical findings and their translational limitations. Chemico-Biological Interactions. 183(3) p. 333–340. DOI 10.1016/j.cbi.2009.11.028.
WAIS MOSSA M.T., MAZET M. 1991. Influence des sels mineraux sur l’adsorption des acides humiques sur flocs d’hydroxydes de fer preformes [Influence of mineral salts on the adsorption of humic acids on iron hydroxide preformed flocs]. Environmental Technology. Vol. 12(8) p. 725–730.
WALLACE J. 1996. Phenol. In: Kirk-Othmer encyclopedia of chemical technology. 4 th ed. New York. John Wiley and Sons p. 592–602.
WANG G.S., KANG S.F., YANG H.J., PAI S.Y., CHEN H.W. 2002. Elimination of dissolved natural organic matter from source water with alum coagulation. Environmental Technology. Vol. 23 p. 1415–1423.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-e184d01a-3ddd-4a95-a80d-ddc74640944e