NEW GALVANIC CELL DESIGNS FOR MINIMIZING ELECTRODE POLARIZATION

New galvanic cell designs, incorporating one or two buffer electrodes, are developed to minimize the electrode polarization caused by electr ochemical permeability of the electrolyte at high temperature: When a nonpolarizable reference electrode is employed, a cell with three-elec trode compartments can be used to measure the chemical potential of ox ygen in two-phase fields of ternary systems, associated with one degre e of freedom at constant temperature. A buffer electrode is placed bet ween the reference and measuring electrodes. The buffer electrode, mai ntained at approximately the same oxygen chemical potential as the mea suring electrode, absorbs the semipermeability flux of oxygen between reference and measuring electrodes. When the reference electrode is po larizable, two buffer electrodes are required between the reference an d measuring electrodes. The reference and reference-buffer electrodes have the same chemical potential of the active species. Similarly the measuring electrode and its buffer are of approximately the same chemi cal potential. A significant chemical potential difference exists only between the two buffers, which may become polarized due to coupled tr ansport of ions and electronic defects through the electrolyte. Since the reference and measuring electrodes are insulated, the emf of the s olid state cell is unaffected. The use of the buffer electrode designs permit more accurate thermodynamic measurements on metal and ceramic systems at high temperature.