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Potentiometry and the Detection of Fluoride
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pH Meter pH meters use a ion selective glass electrode:
Thin glass membrane connects sample with a reference solution Glass membrane typically made of silica Potential difference builds across membrane potential difference depends on ions concentrations on either side of glass membrane pH meter selective for H+ ions Skoog, Douglas A., and Leary, James. J. Principles of Instrumental Analysis. Fort Worth: Saunder College Publishing, Print.
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Glass Membrane Electrode
Conduction is achieved by ion exchange between singly charged cations on the glass lattice with H+ from solution: H+ + Na+Glass Na+ + H+Glass- Then between internal solution and glass H+Glass H+ + Glass- SiO4 Glass Membrane Skoog, Douglas A., and Leary, James. J. Principles of Instrumental Analysis. Fort Worth: Saunder College Publishing, Print. Cation (Na+ or H+) Oxygen Silica
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Ion Selective Electrodes
Highly selective for a specific ion Selective binding to analyte by ion exchange, crystallization, or complexation Types of Ion Selective Electrodes Crstyalline Membrane Electrodes Ex: LaF3 for F- Non crystalline Membrane Electrodes Ex: Silicate glass for Na+ and H+ Skoog, Douglas A., and Leary, James. J. Principles of Instrumental Analysis. Fort Worth: Saunder College Publishing, Print.
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Lanthanum Fluoride Electrode
Crystalline membrane electrode of LaF3, a natural conductor Doping with EuF2 which has one less F- anion Vacancies in crystal structure allow for ion “hopping” and thus a conduction of charge Interference by: hydroxide ion at pH > 8 Vacancy F- La3+ Eu2+ LaF LaF2+ + F- Skoog, Douglas A., and Leary, James. J. Principles of Instrumental Analysis. Fort Worth: Saunder College Publishing, Print. Ion Hopping in a Doped Lanthium Fluoride Electrode F- anions move through vacancies.
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Selectivity Electrodes can also be sensitive to ions of the same charge can cause interference need to evaluate sensitivity of your technique to other interferents Activity, not concentration, is directly measured Total ionic strength of buffer kept constant to minimize ionic effects Skoog, Douglas A., and Leary, James. J. Principles of Instrumental Analysis. Fort Worth: Saunder College Publishing, Print.
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Potentiometry Measure potential difference develops from fluoride ions present Use potentiometer: high impedance voltmeter that draw virtually no electrical current Ion concentration can be determined from the measured potential using the Nernst Equation: Can be used to determine fluoride concentration in drinking water E = E0-(RT/nF)lnQ Skoog, Douglas A., and Leary, James. J. Principles of Instrumental Analysis. Fort Worth: Saunder College Publishing, Print. E is the potential difference E0 is the standard cell potential Q = [ion outside]/[ion inside] R, F are constants T is temperature n is # of e-
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Fluoridation Since 1945, communities across the United States have been adding fluoride (F-) to public water supplies. Fluoride fights tooth decay Optimal fluoride level recommended for the prevention of tooth decay: parts per million
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Fluoridation One of three compounds typically added:
Sodium Fluoride: crystalline form easy to handle, but expensive; reference standard Fluorosilicic acid: liquid by product of phosphate fertilizer manufacture; expensive distribution (shipping) Sodium Fluorosilicate: powder, fine crystal; easy to ship Na+ -F Fluoridation does not change taste, smell, or appearance of drinking water.
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Experimental Results Calibration curve constructed using public water samples. Higher concentrations of fluoride are associated with more negative potential Linear until very low concentrations Fluoride Ion (ppm) Frant, MS and Ross, James W. "Use of a Total Ionic Strength Adjustment Buffer for ELectrode Determination of Fluoride in Water Supplies." Analytical Chemistry (1968). 40(7): Millivolts
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Experimental Results INSERT HUMAN DATA
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