This laboratory consists of a physical model of a municipal drinking water distribution network aimed at better management of these networks. The infrastructure replicates a typical sector of a municipal drinking water system. The pipes are about 2/3 of the actual diameter and pressure of a real network. The network is equipped with numerous sensors (flow, pressure, conductivity), pressure regulators, isolation valves and faucets (to simulate water usage or leaks) that are all connected to a central computer system . The assembly is designed to be more versatile.
Analysis of trace metals in liquid or solid samples (biological tissues, suspended matter, sediments, soils) and bio-optical analysis. Research focuses on the path of toxic metals in the food chain, the bioavailability of contaminants, the impacts of anthropogenic activities and the assessment of the sensitivity of the natural environment. The main equipment is as follows: Particle and radioactivity counters (beta and gamma emissions); Atomic and mass emission spectrometers, by inductively coupled plasma (ICP-AES and ICP-MS); Liquid, gas and ion chromatography devices (HPLC, LC-MS-MS, GC, GC-MS); ICP-MS coupled to an HPLC; Mercury analyzer.
These laboratories make it possible to analyze water samples by colorimetry, fluorometry, spectroscopy, radioisotopy and chromatography, as well as to analyze organic compounds and trace metals present in different matrices (water, effluents, sewage sludge, soils, sediments, biological tissues), and finally, to analyze the elements present in solid samples (rocks, soils, sediments, sludge). X-ray microfluorescence scanning: Non-destructive x-ray analyzes coupled with chemical X-ray fluorescence analysis of rocks, soils and sediments. Scanning electron microscopy: Production of high resolution images of the surface and composition of a sample using technology using electron-matter interactions.