Cyanide Generation During Preservation of Chlorinated Wastewater Effluent Samples for Total Cyanide Analysis

Khoury, Joseph; Pang, Maria; Young, Connie; Pandit, Anita; Carr, Steve; Fischer, Dwayne; Stahl, James F.

doi:10.2175/106143007x220743

Cited by 6 publications

(4 citation statements)

References 14 publications

(15 reference statements)

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“…Though more complex than drinking water, cyanide formation has been studied more extensively in domestic and industrial wastewater . Several wastewater studies have shown the cyanide can form during preservation and storage – . Weinberg, et al , concluded that “an unknown, reactive, carbon-containing compound reacts with chlorine to form a cyanide precursor compound.…”

Section: Resultsmentioning

confidence: 99%

“…In an extensive study of hundreds of samples collected at four California wastewater treatment plants , , virtually all of the samples tested without pH preservation were nondetect for CN − at 5 µg/L, regardless of the dechlorinating agent used. But when these same samples were preserved by being adjusted to pH >12, cyanide tended to be detected.…”

Section: Resultsmentioning

confidence: 99%

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False Cyanide Formation during Drinking Water Sample Preservation and Storage

Delaney¹,

Blodget²,

Hoey³

et al. 2007

Environ. Sci. Technol.

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Carefully controlled bench-scale and on-site experiments demonstrated that cyanide can form in the treated drinking water sample container during preservation and storage. In the bench-scale experiment, treated tap water samples were collected on 20 days over six months. The tap water samples were split and some of the splits were spiked with formaldehyde, a known ozone disinfection byproduct, held for three hours and tested for cyanide. Then they were preserved and held for 2-10 days. None of the 69 initial samples had cyanide detects, but 22 of 49 formaldehyde-spiked samples and three of the 20 unspiked samples developed detectable cyanide concentrations during storage. In the on-site experiment, six samples were collected at a finished water tap at an ozone/chloramination treatment plant over three days. Each sample was split, and a portion was spiked with formaldehyde. Each portion was analyzed in triplicate after three different procedures: (1) immediately distilled on-site, (2) stabilized on-site in a distillation tube and distilled back at the laboratory several days later, or (3) following the conventional procedure of preserving the sample to pH > 12 in a container and distilling the sample back at the laboratory. Only the samples handled in the conventional way had detectable amounts of cyanide. Both experiments demonstrated that cyanide can form during conventional preservation and storage, and it is likely that the cyanide detected for this treated drinking water was formed in the sample container as a consequence of the preservation and storage conditions.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

False Cyanide Formation during Drinking Water Sample Preservation and Storage

Delaney¹,

Blodget²,

Hoey³

et al. 2007

Environ. Sci. Technol.

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“…This regulatory mantra is problematic for cyanide (Delaney & Blodget 2016a), and similar false positives from the sample preservation and testing have been demonstrated (Delaney et al 2007). Cyanide formation during wastewater preservation and testing has also been demonstrated (Stanley & Antonio 2012, Khoury et al 2008, Carr et al 1997, Delaney et al 1997). For wastewater, some treatment plants have been allowed by their regulators to avoid adding NaOH if they start the distillation immediately after sample collection, though USEPA stated that this is not allowed for drinking water (Wendleken 2016).…”

Section: Discussionmentioning

confidence: 98%

Free Cyanide Forms During Determination of Free Cyanide in Drinking Water

Delaney¹,

Blodget²

2017

Journal AWWA

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Easily detectable amounts of free cyanide (FCN) were formed when deionized water was treated like drinking water and preserved and tested for FCN. This occurred when either ascorbic acid or thiosulfate was used to dechlorinate, though higher FCN concentrations were observed with ascorbic acid. The amount of FCN observed was up to 50–60 µg/L but strongly depended on the concentration of ascorbic acid used. The amount of FCN observed was less dependent on the amount of thiosulfate used. The FCN was observed immediately after the samples were preserved, tended to increase—primarily during the first 24 h—and persisted for at least five days. This demonstrates the potential to get false positive FCN results on drinking water samples that a US public water system would be required to report in its annual Consumer Confidence Report. Since drinking water sampling, preservation, and testing is prescriptive, there are few available ways to avoid these false positives.

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“…In 1994 an EPA consultant stated that the approved total cyanide methods in wastewater at that time were “dysfunctional” (Goldberg, 1994). Since then a number of researchers have examined the performance of various analytical methods for various forms of cyanide and the impact of sample preservation and pretreatments for positive and negative interferences (Milosavljevic, 1995; Carr, 1997; Weinberg and Cook, 2002; Zheng, 2003; Deeb, 2003; Gulino, 2004; Zheng, 2004a‐d; Zheng, 2004; Weinberg et al, 2005; Khoury et al, 2005; Pandit et al, 2006; Khoury et al, 2008; Stanley and Antonio, 2012). For example, Stanley and Antonio (2012) showed that preservation of wastewater samples with sodium hydroxide caused an “artificial increase” in cyanide levels compared to unpreserved samples and that this increase was not a matrix interference.…”

Section: Introductionmentioning

confidence: 99%

Total Cyanide Field Spikes for Industrial Wastewater Samples Verify Successful Sample Integrity, Preservation, Pre‐Treatment and Testing

Delaney

Blodget²

2015

Water Environment Research

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Obtaining accurate and precise results for total cyanide concentrations in wastewater samples is fraught with positive and negative interferences. Even the United States Environmental Protection Agency has acknowledged that it may be difficult or impossible to adequately mitigate all interferences. We demonstrated that a field spike of complex cyanide can be successfully used to demonstrate when sampling, preservation, pre-treatment, and analysis techniques are working adequately to retain any cyanide present in the sample without causing false positives or false negatives. For 257 industrial wastewater effluent samples collected at a wide variety of Greater Boston industries, 237 (92.2%) had usable field spike recoveries, averaging 86.2% recovery. Field spike recoveries for problematic industries that had very high or very low field spike recoveries were useful to show when alternative preservations and field dilutions were successfully preserving total cyanide. The field spike approach is general and should also work in a similar manner for raw and treated drinking water samples.

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Cyanide Generation During Preservation of Chlorinated Wastewater Effluent Samples for Total Cyanide Analysis

Cited by 6 publications

References 14 publications

False Cyanide Formation during Drinking Water Sample Preservation and Storage

False Cyanide Formation during Drinking Water Sample Preservation and Storage

Free Cyanide Forms During Determination of Free Cyanide in Drinking Water

Total Cyanide Field Spikes for Industrial Wastewater Samples Verify Successful Sample Integrity, Preservation, Pre‐Treatment and Testing

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