MEASURING LEAD IN WATER AS PER ISO:15586:2003
Applications | 2018 | Agilent TechnologiesInstrumentation
Monitoring lead in drinking water is vital due to its toxicity and widespread exposure through water supplies. Compliance with the WHO guideline of 10 μg/L ensures public health protection.
This application brief demonstrates the determination of trace lead in water samples following ISO 15586:2003. It covers method optimization, validation and real-world performance using graphite furnace atomic absorption spectrometry (GFAAS).
The protocol employs a chemical modifier (ammonium dihydrogen phosphate and magnesium nitrate) to improve analyte stability. Sample and standard preparation involved a 50 μg/L lead standard and a certified reference material (SPS SW2 at 25.0 μg/L). Temperature steps were optimized via a chemometric Surface Response Methodology tool for ash and atomization.
Key performance metrics for a 20 μL sample volume include:
The optimized GFAAS method offers cost-effective, rapid and reliable lead determination in drinking water. It supports regulatory monitoring, quality control in water treatment and public health surveillance.
Advances may include integration of machine learning for real-time optimization, miniaturized detectors for field analysis, and coupling with hyphenated techniques to expand multi-element capabilities.
The Agilent 240Z GFAAS system delivers robust performance for lead analysis in water per ISO 15586:2003, combining sensitivity, accuracy and operational efficiency.
AAS
IndustriesEnvironmental
ManufacturerAgilent Technologies
Summary
Significance of the Topic
Monitoring lead in drinking water is vital due to its toxicity and widespread exposure through water supplies. Compliance with the WHO guideline of 10 μg/L ensures public health protection.
Objectives and Study Overview
This application brief demonstrates the determination of trace lead in water samples following ISO 15586:2003. It covers method optimization, validation and real-world performance using graphite furnace atomic absorption spectrometry (GFAAS).
Methodology
The protocol employs a chemical modifier (ammonium dihydrogen phosphate and magnesium nitrate) to improve analyte stability. Sample and standard preparation involved a 50 μg/L lead standard and a certified reference material (SPS SW2 at 25.0 μg/L). Temperature steps were optimized via a chemometric Surface Response Methodology tool for ash and atomization.
Used Instrumentation
- Agilent 240Z Atomic Absorption Spectrometer with transverse Zeeman background correction
- GTA 120 Graphite Tube Atomizer with Constant Temperature Zone design
- PSD 120 Programmable Sample Dispenser autosampler
- Pyrolytic platform Omega tube and high-purity (99.99%) argon gas
Main Results and Discussion
Key performance metrics for a 20 μL sample volume include:
- Characteristic concentration (peak area): 0.85 μg/L
- Characteristic mass (peak area): 13.9 pg
- Detection limit: 0.15 μg/L
- Quantification limit: 0.50 μg/L
- Recovery of SRM: 100.1%
- Recovery of spiked sample: 103.6%
Benefits and Practical Applications
The optimized GFAAS method offers cost-effective, rapid and reliable lead determination in drinking water. It supports regulatory monitoring, quality control in water treatment and public health surveillance.
Future Trends and Opportunities
Advances may include integration of machine learning for real-time optimization, miniaturized detectors for field analysis, and coupling with hyphenated techniques to expand multi-element capabilities.
Conclusion
The Agilent 240Z GFAAS system delivers robust performance for lead analysis in water per ISO 15586:2003, combining sensitivity, accuracy and operational efficiency.
References
- ISO 15586:2003. Water Quality. Determination of trace elements using atomic absorption spectrometry with graphite furnace.
- ISO 15587-1:2002. Water quality—Digestion for the determination of selected elements in water—Part 1: Aqua regia digestion.
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
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