Water Testing: How we measure what you can’t see

1. Water Testing:How we measure what you can’t see 1st Elmvale Water Festival August 4, 2007 Ray Clement Laboratory Services Branch, Ontario Ministry of the Environment

2. Overview • Steps taken to analyze water • What is trace? • How do we know we’re right? • New environmental issues and challenges

3. Steps in Water Analysis • Determine objectives • Take a sample for testing • Prepare sample for analysis • Analyze sample • Interpret results with quality control

4. Objectives of Water Analysis • Ensure safety of drinking water • Emergency Response (e.g., industrial spills) • Litigation • Research The specific methods used depend on the study objectives, type of water tested (drinking, surface, other), and other factors

5. Sampling Considerations • Sample taken must be representative of the water body being tested

6. Sampling Artifact?

7. Sampling Considerations • Sample taken must be representative of the water body being tested • Sampling containers must be appropriate and specially cleaned before use (e.g., plastic for metals, glass for organics) • Shipping and storage considerations

8. Prepare Sample for Analysis • Extraction step • Interference removal step • Concentration step

9. Extraction Step • Methods used depend on substance we are testing for • For organic chemicals like PCBs or pesticides, use organic solvent not miscible with water • Sometimes, water filtered and particulates extracted separately

10. Water Extraction Setup • In this example, hexane was added to a 1.0 Liter drinking water sample • When the water and solvent are mixed vigorously, organic molecules move from water into the solvent

11. Water Extraction Setup • After the water and solvent have mixed well, the solvent is withdrawn from the top – this process is repeated 2-3 times to make sure all organic compounds are removed

12. Solids Extraction Setup • If particulates are in water, they are filtered and the filter extracted by Soxhlet • Solvent in the flask at the bottom is continually recycled, bringing organic chemicals to the bottom • Process similar to brewing coffee

13. Interference Removal Step • The compounds you are looking for are not the only ones in the sample • Other compounds – Interferences – can result in incorrect results • Interferences are removed by various chemical operations known as Cleanup

14. Interference removal example for dioxin analysis

15. Concentration Step • The sample must be reduced in size before analysis because it is too dilute to achieve really low detection limits • ppb = parts-per-billion [1 part in 109] • ppt = parts-per-trillion [1 part in 1012] • ppq = parts-per-quadrillion [1 part in 1015]

16. Typical Concentration Factors • Typical water sample size for trace analysis is about 1.0 Litres • Final sample 10-100 microlitres (10-6 L) • Concentration factor is about 104 to 105

17. Other environmental sample types

18. Sample Analysis Considerations • Many different types of chemical instrumentation are available for the final analysis step • For metals, one of most effective is called an Inductively-Coupled Plasma Mass Spectrometer (ICP-MS)

19. ICP-MS Metals Analysis • ICP-MS uses a hot plasma (flame) to atomize metals in sample • Metals identified by atomic mass • Number of atoms detected related to concentration in sample

20. GC-MS Organics Analysis • For organics, instrumentation used is called a gas chromatograph-mass spectrometer (GC-MS) • Dozens of types of GC-MS systems exist, costing from $100K to $1.5 million • Capabilities of systems different, but basic principles the same

21. Inject Sample Into GC-MS

22. Complexity of Soil Samples

23. Basic Operation of GC-MS

24. Each Molecule has Fingerprint

25. High Resolution Mass Spectrometer

26. Characteristics of Methods • Detection Limit • Accuracy • How close to the real concentration? • Precision • Related to measurement uncertainty

27. Detection Limits

28. Detection Limits

29. Precision and Accuracy

30. Data Interpretation: Public Understanding • Analysis of dioxin in lake water • 3 samples on consecutive days • Detection limits 0.1 – 0.3 ppt • Actual results: • Day 1 – 0.2 ppt • Day 2 – 0.4 ppt • Day 3 – not detected • What was the newspaper headline?

32. New Millennium – New Challenges • Pharmaceuticals & Personal Care Products • Perfluorinated compounds • Water Disinfection Byproducts • Brominated Flame Retardants (BFRs) • Algal Toxins: microcystins, anatoxins • Organometallic Compounds: tin, lead

33. The Future ofEnvironmental Trace Analysis More of less, faster and cheaper

34. How Many Chemicals? Date: 08/1/2007 11:14:18 EST Count:  32,261,560 organic/inorganic substances15,057,189 commercially available chemicals

35. New Challenges: New Tools • Fourier Transform (Ion Cyclotron Resonance) Mass Spectrometer