Lanthanides release and partitioning in municipal wastewater effluents

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dc.contributor.author

Turcotte, Patrice

Smyth, Shirley Anne

Gagné, François

Gagnon, Christian

dc.date.accepted

2022-05-15

dc.date.accessioned

2024-01-24T19:22:22Z

dc.date.available

2024-01-24T19:22:22Z

dc.date.issued

2022-05-17

dc.date.submitted

2022-04-19

dc.description.abstract - en

The use of lanthanides is increasing in our society, whether in communication technologies, transportation, electronics or medical imaging. Some lanthanides enter urban wastewater and flow through municipal wastewater treatment plants (WWTPs). However, little is known about the effectiveness of treatment processes to remove these elements and the concentrations released in effluents to receiving waters. The main objective of this study was to investigate the fate of lanthanides in various wastewater treatment processes. A secondary objective was to better understand the fate of medical gadolinium (Gd) complexes; anthropogenic inputs were differentiated from geological sources using an approach based on concentration normalization with respect to chondrite Post-Archean Australian Shale (PAAS). The hypothesis was that most lanthanides, especially of geological origin, are associated with the particulate phase and could be efficiently removed by WWTPs. To monitor these elements in different WWTPs, various urban influents and effluents from simple aerated lagoons to advanced treatments were sampled in Canada. The results showed that the rates of lanthanide removal by treatment processes decrease with their atomic number; from 95% for cerium (Ce) to 70% for lutetium (Lu), except for Gd, which was minimally removed. The normalization approach permitted the determination of the origin of Gd in these wastewaters, i.e., medical application versus the geological background. By distinguishing the geogenic Gd fraction from the anthropogenic one, the removal efficiency was evaluated according to the origin of the Gd; nearly 90% for geogenic Gd and a rate varying from 15% to 50% in the case of anthropogenic Gd. The processes using alum as the flocculating agent had the highest removal efficiency from wastewater.

dc.identifier.doi

https://doi.org/10.3390/toxics10050254

dc.identifier.issn

2305-6304

dc.identifier.uri

https://open-science.canada.ca/handle/123456789/1895

dc.language.iso

en

dc.publisher

MDPI

dc.rights - en

Creative Commons Attribution 4.0 International (CC BY 4.0)

dc.rights - fr

Creative Commons Attribution 4.0 International (CC BY 4.0)

dc.rights.openaccesslevel - en

Gold

dc.rights.openaccesslevel - fr

Or

dc.rights.uri - en

https://creativecommons.org/licenses/by/4.0/

dc.rights.uri - fr

https://creativecommons.org/licenses/by/4.0/deed.fr

dc.subject - en

Nature and environment

Water

Science and technology

dc.subject - fr

Nature et environnement

Eau

Sciences et technologie

dc.subject.en - en

Nature and environment

Water

Science and technology

dc.subject.fr - fr

Nature et environnement

Eau

Sciences et technologie

dc.title - en

Lanthanides release and partitioning in municipal wastewater effluents

dc.type - en

Article

dc.type - fr

Article

local.article.journalissue

5

local.article.journaltitle

Toxics

local.article.journalvolume

10

local.pagination

13 pages

local.peerreview - en

Yes

local.peerreview - fr

Oui

local.requestdoi

No

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