Drinking Water Testing by Ion Chromatography using Ultrapure Water

These results demonstrate that freshly delivered ultrapure water from a Milli-Q^® IQ 7000 system is well-suited for use in IC analysis. This water may confidently be used for blanks and to preparate samples, standards and eluents. Ultrapure water from the system is also suitable to analyze drinking water as it contains extremely low levels of inorganic ions.

Experimental method

For inorganic anions:

• Instrument: Thermo Scientific Dionex™ ICS-3000 system
• Columns: Anion concentrator: IonPac™ UTAC-ULP1 5 x 23 mm; Guard column: IonPac™ AG19 2 x 50 mm; Analytical column: IonPac™ AS19 2 x 250 mm
• Eluent: KOH gradient: 1 to 35 mM KOH from 0 to 20 min; 35 mM from 20 to 25 min; 35 to 1 mM from 25 to 25.1 min; 1 mM from 25.1 to 30 min
• Eluent source: EG40 with KOH cartridge and ultrapure water from an ICW-3000™ direct IC feed system; Flow rate: 0.25 mL/min
• Detection: Suppressed conductivity; Eluent suppressor: ASRS^® Ultra II 2 mm
• Samples and standards: sample volume was 40 mL (pre-concentrated: 40 mL sample is concentrated on a cartridge, and the concentrated sample is injected on a column after desorption). TraceCERT^® standards were used.

For inorganic cations, the same method was used, but with an MSA gradient and a CS12A analytical column.

IC analysis of disinfection by-products in ultrapure and drinking water samples

To maintain safe drinking water, a critical amount of disinfectant must be added to kill pathogens while also minimizing the production of DBPs to levels that are below acceptable limits.

The EPA⁵ and WHO² have set the maximum level of bromate permissible in tap water at 10 μg/L. The FDA adopts this same regulatory limit for bottled water.⁴ In Europe, natural mineral waters and spring waters treated by ozonation have a maximum permissible bromate limit of 3 μg/L⁶; this value is 10 µg/L for drinking water.¹ Levels of bromate, chlorate and chlorite in drinking water are commonly assessed by IC following EPA method 300.1.⁷

We analyzed tap water and ultrapure water freshly delivered from a Milli-Q^® IQ 7000 system equipped with a Millipak^® final filter. Bromate, chlorate and chlorite levels in the ultrapure water were below the limits set by regulatory bodies (Table 2). Even if some DBPs were present in the feed tap water, DBPs were not detected in the ultrapure water dispensed from the system.

The combination of technologies in the water purification chain (consisting of an Elix^® EDI-based system feeding a Milli-Q^® IQ 7000 system) efficiently removes trace levels of DBPs to produce ultrapure water that is suitable for drinking water analysis by IC.

Experimental method

Analyses were performed by an independent accredited (COFRAC) laboratory.

• Chlorite and chlorate: according to norm NF EN ISO 10304-4
• Bromate: according to norm NF EN ISO 15061
• Eluent: carbonate/bicarbonate
• Column: Metrohm Metrosep A supp 7 – 250/4.0, 45 °C, suppressed conductivity detection

Suitability of ultrapure water produced by a Milli-Q^® water purification system for the IC analysis of drinking water

This study demonstrates that ultrapure water freshly produced by a Milli-Q^® IQ 7000 water purification system is suitable for the tasks performed as part of the IC analysis of drinking water. Specifically, for the preparation of eluents, samples, and standards, and for use as blanks. Even if the tap water feeding the system contains the ions to be measured, these contaminants are removed by the combination of technologies present in the water purification chain. 

A Milli-Q^® IQ 7000 ultrapure water system can be fed by an Milli-Q^® IX pure water system, which includes Elix^® EDI technology. Alternatively, a Milli-Q^® IQ 7003/05/10/15 pure and ultrapure system dispenses ultrapure water suitable for IC analysis using tap water as its feed source.