Adsorption stages and interfacial orientations of cytidine sulphate at the mercury/electrolyte interface

Recently, there has been muchinterest in the useof trifluoromethanesulfonic acid as anelectrolyte in advanced fuel cell systems because of the enhanced rate of oxygen reduction in this medium. In order to elucidate this characteristic from a double layer point of view, the present work was undertake

The absorption behavior of uracil at the mercury/electrolyte interface was studied by ekctrocapillary and capacitance measurements. Three different adsorption states (SI, SII, SIII) can be distinguished, depending on adsorbate concentration, temperature and potential. State I corresponds to a layer

The adsorption of M-naphthalenesulfonate, B-naphthalenesulfonate and 1, 5-naphthalenedisulfonate ions on mercury from an aqueous solution at constant ionic strength has been investigated by measurement of the double layer capacity as a function of concentration. The adsorption can be represented by

The adsorption and the changes in the interfacial composition of octanoic acid at the mercury/electrolyte interface was studied by measuring the differential capacitance at different concentrations of the supporting electrolyte, at various supporting electrolyte systems and at various temperatures.

The adsorption of cetyltrimethyammonium bromide (CTAB) on a hanging mercury electrode is studied in various electrolyte systems and temperatures. A condensed film is formed at negative potentials and at room temperature only in the presence of KBr. The decrease of the temperature favors the formatio

## dynamics are usually considerably changed by coadsorption The adsorption of a purified solution of octanoic acid at the (6,7). As already reported in (7) it is indispensable to use mercury/solution and air/water interfaces was studied. The equisurfactant solutions with a sufficient grade of pur