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Development of Fluorescent Probes for Environmental Sensing and Detection of Heavy Metals. Xiu R. (James) Bu Department of Chemistry Clark Atlanta University March 10, 2003. Initial state: localized. Problem. development. Delocalization . Penetration. Soil. Water.
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Development of Fluorescent Probes for Environmental Sensing and Detection of Heavy Metals Xiu R. (James) Bu Department of Chemistry Clark Atlanta University • March 10, 2003
Initial state: localized Problem development Delocalization Penetration Soil Water Final state: soil and underground water contamination Human Background-Problems-Destination of toxic metals Government sites: production and storage sites of weapons; nuclear power plant (cobalt from coolant water). Industrial sites metal plating; battery production/recycling (Pb and Ni); tanneries, fertilizers, and metal cleaning, etc.
Toxic heavy metals:Long-term exposure effects Cobalt-asthma like allergy, damage to heart, thyroid, and liver. Also cause mutation to living cells Nickel-carcinogenic, heart and liver damage Copper-liver damage Lead--nerve damage, brain and liver damage Mercury-kidney damage Chromium-irritant to nose, skin, and stomach; liver and kidney damage. Cadmium-lung damage,lung cancer, and high blood pressure
EPA’s current drinking water standards Cobalt N/A Nickel 0.1 mg/L Copper 1.3 mg/L Lead 0.05 mg/L Mercury 0.002 mg/L Chromium 0.1 mg/L Cadmium 0.01 mg/L Sensing sensitivity must be available in these ranges.
Area One: Remediation Goal: to remove toxic heavy metals. How ? Choices: using chemicals to remove chemicals or using natural components to remove chemicals. Wood- natural fiber, practically cost least !!! Readily available in vast amount !!!
Chemistry for possible modification of wood surface to enhance chelating capability
For A For B Development of wood fiber based remediation technology • For example: liquid filters
Area Two: Detection Goal: To seek a fast and portable as well as continuous monitoring probes. Advantages of Fluorescence Probes: Highly sensitive Less Interference Tunable for wide applications (wavelength/selectivity)
Fluorophores Fluorophores Chelating unit Florescent unit I h c Upon chelating action, the fluorescence signal disappears or diminishes. Before chelating S1 S1 non-radiative So So A working fluorescent probe analyte Sensing result
Technical approaches Fluorescent unit Highly emission intensity-high sensitivity Near IR emission reducing interference Ligand unit Fast action for chelating Enhanced selectivity for target analytes Design features N N N O O O O N N O Design features: D-A based dyes Supramolecular structure-based (dendritic, allosteric…) bi-dentate tetradentate Molecular probes Polymer based probes
Technical approaches (cont.) Polymer backbone ligand Chemical structure of a typical fluorophore Tetrahedron Lett. 42, 805(2001). Tetrahedron Lett. 37, 7331 (1996). Polym. Prep. 37(1), 599 (1996). Configuration of polymer based probes fluorophore Chemical structure of a typical polymer probe
Expected measurable achievements Publications-refereed journals Students training Technology transfer Academic collaboration Government collaboration