520 likes | 2.39k Vues
Potentiometry. Potential measurements of electrochemical cells Ion selective methods Reference electrode Indicator electrode Potential measuring device Reference electrode Indicator electrodes Ion specific electrodes Potentiometric measurements. Reference electrode. Known half-cell
E N D
Potentiometry • Potential measurements of electrochemical cells • Ion selective methods • Reference electrode • Indicator electrode • Potential measuring device • Reference electrode • Indicator electrodes • Ion specific electrodes • Potentiometric measurements
Reference electrode • Known half-cell • Insensitive to solution under examination • Reversible and obeys Nernst equation • Constant potential • Returns to original potential • Calomel electrode • Hg in contact with Hg(I) chloride • Ag/AgCl
Indicator electrode • Ecell=Eindicator-Ereference • Metallic • 1st kind, 2nd kind, 3rd kind, redox • 1st kind • respond directly to changing activity of electrode ion • Direct equilibrium with solution
Ion selective electrode • Not very selective • simple • some metals easily oxidized (deaerated solutions) • some metals (Zn, Cd) dissolve in acidic solutions • Ag, Hg, Cu, Zn, Cd, Bi, Tl, Pb
2nd kind • Precipitate or stable complex of ion • Ag for halides • Ag wire in AgCl saturated surface • Complexes with organic ligands • EDTA • 3rd kind • Electrode responds to different cation • Competition with ligand complex
Metallic Redox Indictors • Inert metals • Pt, Au, Pd • Electron source or sink • Redox of metal ion evaluated • May not be reversible • Membrane Indicator electrodes • Non-crystalline membranes: • Glass - silicate glasses for H+, Na+ • Liquid - liquid ion exchanger for Ca2+ • Immobilized liquid - liquid/PVC matrix for Ca2+ and NO3- • Crystalline membranes: • Single crystal - LaF3 for FPolycrystalline • or mixed crystal - AgS for S2- and Ag+ • Properties • Low solubility - solids, semi-solids and polymers • Some electrical conductivity - often by doping • Selectivity - part of membrane binds/reacts with analyte
Glass membrane structure • H+ carries current near surface • Na+ carries current in interior • Ca2+ carries no current (immobile)
Boundary Potential • Difference in potentials at a surface • Potential difference determined by • Eref 1 - SCE (constant) • Eref 2 - Ag/AgCl (constant) • Eb • Eb = E1 - E2 = 0.0592 log(a1/a2) • a1=analyte • a2=inside ref electrode 2 • If a2 is constant then • Eb = L + 0.0592log a1 • = L - 0.0592 pH • where L = -0.0592log a2 • Since Eref 1 and Eref2 are constant • Ecell = constant - 0.0592 pH
Alkaline error • Electrodes respond to H+ and cation • pH differential • Glass Electrodes for Other Ions: • Maximize kH/Na for other ions by modifying glass surface • Al2O3 or B2O3) • Possible to make glass membrane electrodes for • Na+, K+, NH4+, Cs+, Rb+, Li+, Ag+
Crystalline membrane electrode • Usually ionic compound • Single crystal • Crushed powder, melted and formed • Sometimes doped (Li+) to increase conductivity • Operation similar to glass membrane • F electrode
Liquid membrane electrodes • Based on potential that develops across two immiscible liquids with different affinities for analyte • Porous membrane used to separate liquids • Selectively bond certain ions • Activities of different cations • Calcium dialkyl phosphate insoluble in water, but binds Ca2+ strongly
Molecular Selective electrodes • Response towards molecules • Gas Sensing Probes • Simple electrochemical cell with two reference electrodes and gas permeable PTFE membrane • allows small gas molecules to pass and dissolve into internal solution • O2, NH3/NH4+, and CO2/HCO3-/CO32-
Biocatalytic Membrane Electrodes • Immobilized enzyme bound to gas permeable membrane • Catalytic enzyme reaction produces small gaseous molecule (H+, NH3, CO2) • gas sensing probe measures change in gas concentration in internal solution • Fast • Very selective • Used in vivo • Expensive • Only few enzymes immobilized • Immobilization changes activity • Limited operating conditions • pH • temperature • ionic strength
Coulometry • Quantitative conversion of ion to new oxidation state • Constant potential coulometry • Constant current coulometry • Coulometric titrations • Electricity needed to complete electrolysis measured • Electrogravimetry • Mass of deposit on electrode
Constant voltage coulometry • Electrolysis performed different ways • Applied cell potential constant • Electrolysis current constant • Working electrode held constant • ECell=Ecathode-Eanode +(cathode polarization)+(anode polarization)-IR • Constant potential, decrease in current • 1st order • It=Ioe-kt • Constant current change in potential • Variation in electrochemical reaction • Metal ion, then water
Analysis • Measurement of electricity needed to convert ion to different oxidation state • Coulomb (C) • Charge transported in 1 second by current of 1 ampere • Q=It I= ampere, t in seconds • Faraday (F) • Charge in coulombs associated with mole of electrons • 1.602E-19 C for electron • F=96485 C/mole e- • Q=nFN • Find amount of Cu2+ deposited at cathode • Current = 0.8 A, t=1000 s • Q=0.8(1000)=800 C • n=2 • N=800/(2*96485)=4.1 mM
Coulometric methods • Two types of methods • Potentiostatic coulometry • maintains potential of working electrode at a constant so oxidation or reduction can be quantifiably measured without involvement of other components in the solution • Current initially high but decreases • Measure electricity needed for redox • arsenic determined oxidation of arsenous acid (H3AsO3) to arsenic acid (H3AsO4) at a platinum electrode. • Coulometric titration • titrant is generated electrochemically by constant current • concentration of the titrant is equivalent to the generating current • volume of the titrant is equivalent to the generating time • Indicator used to determined endpoint