Major ion toxicity in effluents: A review with permitting recommendations

Major ion toxicity in effluents: A review with permitting recommendations

Effluent toxicity testing methods have been well defined, but for the most part, these methods do not attempt to segregate the effects of active ionic concentrations and ion imbalances upon test and species performances. The role of various total dissolved solids in effluents on regulatory complianc...

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Bibliographic Details
Published in:Environmental toxicology and chemistry Vol. 19; no. 1; pp. 175 - 182
Main Authors: Goodfellow, William L., Ausley, Lawrence W., Burton, Dennis T., Denton, Debra L., Dorn, Philip B., Grothe, Donald R., Heber, Margarete A., Norberg-King, Teresa J., Rodgers Jr, John H.
Format: Journal Article
Language:English
Published: Hoboken Wiley Periodicals, Inc 01-01-2000
Subjects:
Ion imbalance
Salinity
Total dissolved solids
Whole effluent testing
USA
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Summary:Effluent toxicity testing methods have been well defined, but for the most part, these methods do not attempt to segregate the effects of active ionic concentrations and ion imbalances upon test and species performances. The role of various total dissolved solids in effluents on regulatory compliance has emerged during the last few years and has caused confusion in technical assessment and in permitting and compliance issues. This paper assesses the issue of ionic strength and ion imbalance, provides a brief summary of applicable data, presents several case studies demonstrating successful tools to address toxicity resulting from salinity and ion imbalance, and provides recommendations for regulatory and compliance options to manage discharges with salinity/ion imbalance issues. Effluent toxicity resulting from inorganic ion imbalance and the ion concentration of the effluent is pervasive in permitted discharge from many industrial process and municipal discharges where process streams are concentrated, adjusted, or modified. This paper discusses procedures that use weight‐of‐evidence approaches to identify ion imbalance toxicity, including direct measurement, predictive toxicity models for freshwater, exchange resins, mock effluents, and ion imbalance toxicity with tolerant/susceptible text species. Cost‐effective waste treatment control options for a facility whose effluent is toxic because of total dissolved solids (TDS) or because of specific ion(s) are scarce at best. Depending on the discharge situation, TDS toxicity may not be viewed with the same level of concern as other, more traditional, toxicants. These discharge situations often do not require the conservative safety factors required by other toxicants. Selection of the alternative regulatory solutions discussed in this paper may be beneficial, especially because they do not require potentially expensive or high‐energy–using treatment options that may be ineffective control options. The information presented is intended to provide a better understanding of the role of ion imbalance in aquatic toxicity testing and to provide various recommendations that should be considered in addressing these issues.
Bibliography:istex:325276B810C2AEED4691ECD921FFED0C9F61DD5C
ArticleID:ETC5620190121
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ISSN:0730-7268
1552-8618
DOI:10.1002/etc.5620190121