| #Q001 | monitoring | operational | recommended | Individual Nitrate/Nitrite Sample Preservation and Holding Time | drinking water | Samples to be analysed for nitrate or nitrite individually should be cooled to 4°C and analysed within 48 hours. | Analysis using EPA Method 300.0 or 300.1 for nitrate or nitrite individually | high |
| #Q002 | monitoring | operational | recommended | Combined Nitrate and Nitrite Sample Preservation and Holding Time | drinking water | Samples for combined nitrate and nitrite analysis should be acidified using sulphuric acid to a pH less than 2 and analysed within 28 days (U.S. EPA, 1993). | Analysis using EPA Method 300.0 or 300.1 for combined nitrate and nitrite | high |
| #Q003 | monitoring | reporting | mandatory | Nitrite Correction for EPA Method 353.2 | drinking water | To use this method, a correction must be made for any nitrite present by analysing without the reduction step. | When using EPA Method 353.2 revision 2.1 (automated cadmium reduction with colorimetry) | high |
| #Q004 | monitoring | operational | mandatory | EPA Method 353.2 Sample Preservation | drinking water | Samples must be preserved using sulphuric acid to a pH less than 2 and cooled to 4°C at the time of collection (U.S. EPA, 1993). | When using EPA Method 353.2 revision 2.1 | high |
| #Q005 | operational | treatment | recommended | Minimization of Nitrate Levels | drinking water | Treatment plants should strive to minimize nitrate levels in the treated water. | | high |
| #Q006 | operational | operational | mandatory | Ion Exchange Brine Disposal | drinking water | Regeneration results in a brine waste stream that contains high nitrate concentrations and must be disposed of appropriately. | When using conventional ion exchange process for nitrate removal | high |
| #Q007 | treatment | operational | mandatory | Ion Exchange Post-Treatment Corrosion Control | drinking water | In some cases, post-treatment corrosion control measures must be taken to ensure that corrosion problems do not occur in the distribution system following treatment using ion exchange (Schock and Lytle, 2011). | When mineral imbalances increase the corrosive nature of treated water following ion exchange | high |
| #Q008 | design | treatment | mandatory | Reverse Osmosis System Viability Requirements | drinking water | In general, when utilities are considering reverse osmosis systems primarily for nitrate removal, the systems must demonstrate high nitrate rejection, high water flux and a high recovery rate for the systems to be economically viable | When considering reverse osmosis primarily for nitrate removal | high |
| #Q009 | operational | operational | mandatory | Reverse Osmosis Concentrate Disposal | drinking water | Reverse osmosis rejects a significant portion of the influent water as contaminant-rich brine (Taylor and Wiesner, 1999), and the concentrate discharge must be disposed of appropriately. | When using reverse osmosis | high |
| #Q010 | treatment | operational | mandatory | Reverse Osmosis Post-Treatment Corrosion Control | drinking water | The removal of contaminants can cause mineral imbalances that could increase the corrosive nature of the treated water (Schock and Lytle, 2010). In most cases, post-treatment corrosion control measures need to be taken. | When using reverse osmosis | high |
| #Q011 | operational | treatment | mandatory | Biological Denitrification Optimization | drinking water | As nitrite is an intermediate compound in the reduction of nitrate to nitrogen gas, utilities need to ensure that their systems are optimized so that the biological process is complete and nitrite is not present in the treated water. | When using biological denitrification processes | high |
| #Q012 | monitoring | health | recommended | Distribution System Nitrification Monitoring | drinking water | Utilities that are chloraminating should monitor for nitrite and nitrate in the distribution system in addition to ammonia, total chlorine residual, HPC and other nitrification indicators. | For utilities that are chloraminating | high |
| #Q013 | administrative | operational | recommended | Nitrification Monitoring Program Alert/Action Levels | drinking water | The program should identify system-specific alert and action levels, which can be used to determine the appropriate level of action to address nitrification. | When establishing a nitrification monitoring program | high |
| #Q014 | monitoring | operational | recommended | Triggered Monitoring for Free Ammonia | drinking water | Changes in the trend of priority nitrification parameters (such as total chlorine residual, nitrite and nitrate) in the distribution system should trigger more frequent monitoring of other parameters such as free ammonia. | When trends in priority nitrification parameters change | high |
| #Q015 | operational | health | mandatory | Chlorite Addition Control Strategy Limits | drinking water | Utilities wishing to use chlorite addition as a control strategy should ensure that Health Canada's guidelines for chlorite and chlorate are not exceeded (Health Canada, 2008). | When using chlorite addition to control nitrification | high |
| #Q016 | operational | operational | recommended | Nitrification Prevention Strategy Selection | drinking water | For these reasons, comprehensive strategies aimed at the prevention of nitrification episodes are recommended over strategies aimed at controlling nitrification as they occur. | | medium |
| #Q017 | monitoring | health | recommended | Residential Source Water Testing Prior to Device Installation | drinking water | Before a treatment device is installed, the water should be tested to determine general water chemistry and verify the presence and concentrations of nitrate and nitrite in the source water. | Before installing a residential treatment device | high |
| #Q018 | monitoring | health | recommended | Residential Treatment Device Efficacy Testing | drinking water | Periodic testing by an accredited laboratory should be conducted on both the water entering the treatment device and the finished water to verify that the treatment device is effective. | For residential treatment devices | high |
| #Q019 | operational | operational | recommended | Verification of Residential Component Longevity | drinking water | Consumers should verify the expected longevity of the components in their treatment device as per the manufacturer's recommendations. | For residential treatment devices | high |
| #Q020 | design | health | recommended | Residential Treatment Device Certification Requirement | drinking water | Health Canada does not recommend specific brands of drinking water treatment devices, but it strongly recommends that consumers use devices that have been certified by an accredited certification body as meeting the appropriate NSF International (NSF)/American National Standards Institute (ANSI) drinking water treatment unit standards. | When selecting residential treatment devices | high |
| #Q021 | design | health | recommended | Point-of-Use Installation for Distillation Systems | drinking water | Distillation systems should only be installed at the point of use as the water they have treated may be corrosive to internal plumbing components. | When installing residential distillation systems | high |
| #Q022 | design | health | recommended | Point-of-Use Installation for Reverse Osmosis Systems | drinking water | Reverse osmosis systems should only be installed at the point of use as the water they have treated may be corrosive to internal plumbing components. | When installing residential reverse osmosis systems | high |
| #Q023 | design | health | recommended | Certification of Ion Exchange Systems Construction Materials | drinking water | Health Canada strongly recommends that homeowners ensure that these systems are constructed using materials certified to NSF/ANSI Standard 61 (NSF/ANSI, 2009d). | For residential ion exchange systems | high |
| #Q024 | treatment | health | recommended | Alternative Treatment for Source Water with Sulphate | drinking water | If a nitrate-selective resin is not available, homeowners whose source water contains sulphate should consider the use of an alternative treatment. | When nitrate-selective resin is not available and source water contains sulphate | high |
| #Q025 | monitoring | operational | guidance | Residential Ion Exchange Routine Monitoring | drinking water | It is important to routinely monitor the nitrate concentration in the water treated by ion exchange to ensure that the system is effectively removing nitrate and that chromatographic peaking is not occurring. | When using residential ion exchange treatment | high |
| #Q026 | operational | treatment | mandatory | Ion Exchange Resin Regeneration | drinking water | Once the resin has reached its capacity (i.e., when the nitrate ion begins to appear in significant concentration in the column effluent) the resin must be regenerated using a sodium chloride (salt) solution to reverse the process. | When the ion exchange resin has reached capacity | high |
| #Q027 | design | operational | mandatory | Ion Exchange Operational Considerations | drinking water | Utilities need to give careful consideration to the level of nitrate breakthrough, the percentage of raw water that bypasses ion exchange treatment and the use of partial regeneration when determining the lowest achievable nitrate concentration using ion exchange treatment. | When determining achievable nitrate concentrations for ion exchange systems | high |
| #Q028 | operational | operational | mandatory | Electrodialysis Operational Requirements | drinking water | The main considerations for systems using electrodialysis and electrodialysis reversal for nitrate removal are the operational complexity of the system, disposal of the reject water and the need for pH adjustment of the treated water. | When using electrodialysis or electrodialysis reversal | high |
| #Q029 | operational | treatment | guidance | Residential RO Influent Pre-treatment | drinking water | A consumer may need to pre-treat the influent water to reduce fouling and extend the service life of the membrane. | When using residential reverse osmosis systems to extend service life | high |
| #Q030 | monitoring | operational | mandatory | Nitrification Monitoring Program Site-Specific Evaluation | drinking water | A site-specific evaluation is generally necessary to establish a nitrification monitoring program. | When establishing a nitrification monitoring program for chloraminated systems | high |
| #Q031 | operational | health | recommended | Nitrification Strategy Guideline Compliance | drinking water | Any strategy should also ensure that other Guidelines for Canadian Drinking Water Quality are not exceeded. | When implementing preventive or control measures for nitrification | high |
| #Q032 | design | treatment | mandatory | Reverse Osmosis Pretreatment Requirements | drinking water | Reverse osmosis treatment systems typically require prefiltration for particle removal and often include other pretreatment steps, such as the addition of anti-scaling agents, prechlorination/dechlorination and softening. | When designing municipal scale reverse osmosis systems | high |
| #Q033 | design | treatment | mandatory | Biological Denitrification Post-Treatment Requirement | drinking water | In general, biological denitrification treatment systems require post-treatment to remove biomass and biodegradable organic materials that are present in the reactor effluent. | When using biological denitrification for potable water treatment | high |
| #Q034 | design | treatment | recommended | Nanofiltration Membrane Performance Testing | drinking water | Therefore, testing of the nanofiltration membrane selected for nitrate removal will be an important step for utilities considering this treatment process. | For utilities considering nanofiltration for nitrate removal | high |
| #Q035 | design | operational | recommended | Ion Exchange Resin Selection Considerations | drinking water | The ion exchange capacity and the selectivity of the resin are important considerations when selecting a resin. | When selecting strong base anion or nitrate-selective resins | high |