N-nitrosomorpholine in potable reuse

Caitlin M Glover; Edgard M Verdugo; Rebecca A Trenholm; Eric R V Dickenson

doi:10.1016/j.watres.2018.10.010

N-nitrosomorpholine in potable reuse

Water Res. 2019 Jan 1:148:306-313. doi: 10.1016/j.watres.2018.10.010. Epub 2018 Oct 9.

Authors

Caitlin M Glover¹, Edgard M Verdugo², Rebecca A Trenholm², Eric R V Dickenson³

Affiliations

¹ Water Quality Research and Development Division, Southern Nevada Water Authority, P.O. Box 99954, Las Vegas, NV, 89193-9954, USA. Electronic address: caitlinmeara@gmail.com.
² Water Quality Research and Development Division, Southern Nevada Water Authority, P.O. Box 99954, Las Vegas, NV, 89193-9954, USA.
³ Water Quality Research and Development Division, Southern Nevada Water Authority, P.O. Box 99954, Las Vegas, NV, 89193-9954, USA. Electronic address: eric.dickenson@snwa.com.

PMID: 30390511
DOI: 10.1016/j.watres.2018.10.010

Abstract

As potable reuse guidelines and regulations continue to develop, the presence of N-nitrosamines is a primary concern because of their associated health concerns. In this study, bench-, pilot-, and full-scale tests were conducted to focus on the occurrence and treatment of N-nitrosomorpholine (NMOR) in United States (U.S.) potable reuse systems. Out of twelve U.S. wastewater effluents collected, ambient NMOR was detected in eleven (average = 20 ± 18 ng/L); in contrast, only two of the thirteen surface water and stormwater samples had NMOR. Across all of these samples maximum formation potential by chloramination produced an average increase of 3.6 ± 1.8 ng/L. This result underscores the need to understand the sources of NMOR as it is not likely a disinfection byproduct and it is not known to be commercially produced within the U.S. At the pilot-scale, three potable reuse systems were evaluated for ambient NMOR with oxidation (i.e., chlorination and ozonation), biofiltration, and granular activated carbon (GAC). Both pre-oxidation and biofiltration were ineffective at mitigating NMOR during long-term pilot plant operation (at least eight-months). GAC adsorbers were the only pilot-scale treatment to remove NMOR; however, complete breakthrough occurred rapidly from <2000 to 10,000 bed volumes. For comparison, a full-scale reverse osmosis (RO) potable reuse system was monitored for a year and confirmed that RO effectively removes NMOR. Systematic bench-scale UV-advanced oxidation experiments were undertaken to assess the mitigation potential for NMOR. At a fluence dose of 325 ± 10 mJ/cm²_, UV alone degraded 90% of the NMOR present. The addition of 5 mg/L hydrogen peroxide did not significantly decrease the UV dose required for one-log removal. These data illustrate that efficient NMOR removal from potable reuse systems is limited to RO or UV treatment.

Keywords: Advanced treatment; Biological activated carbon; Granular activated carbon; N-nitrosomorpholine; Ozonation; Potable reuse; Reverse osmosis; UV photolysis.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Filtration
Nitrosamines*
Wastewater
Water Purification*

Substances

Nitrosamines
Waste Water
N-nitrosomorpholine