Published in
Elsevier, Electrochimica Acta, (249), p. 263-270, 2017
DOI: 10.1016/j.electacta.2017.08.021
Elsevier, Electrochimica Acta, (248), p. 505-517, 2017
DOI: 10.1016/j.electacta.2017.07.166
Elsevier, Electrochimica Acta, (248), p. 169-177, 2017
DOI: 10.1016/j.electacta.2017.07.116
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Tools
Passivation/precipitation mechanisms of Al-Cr-Fe Complex Metallic Alloys in acidic chloride containing electrolyte
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Abstract
The “accumulator mixing” technique, including the capacitive and the battery mixing, is a new developing technology for harvesting the salinity gradient energy, in particular of NaCl solutions, e.g. sea and river water. It is based on a couple of electrodes in a vessel, in which two solutions of different salinity are alternately fluxed. A current flows through the electrodes and its direction is cyclically inverted. Due to the variation of the electrode potentials induced by the salinity change, the charge is extracted from the cell at a higher voltage than applied during the charging phase: this results in a production of energy at the expenses of the salinity difference. We focus on two kinds of electrode materials: chemically modified activated carbon and battery-like electrodes performing redox reactions, with a cycle operated at constant current. We test them with feed solutions at 20 and 500 mM of NaCl. We show that the CAPMIX power production can be easily predicted from the information obtained by galvanostatic cycles performed at constant concentration; indeed, the periodic salinity changes do not significantly affect the overvoltage observed during the parts of the “accumulator mixing” cycle that takes place at constant salinity. The kinetics of the electrodes in the “accumulator mixing” cycle can thus be easily related to the results of classical electrochemical measurements, such as the impedance spectroscopy. In particular, we show that the most relevant parameter that determines the power production of the cell is the real part of the impedance, measured at the frequency of the CAPMIX cycles, i.e. in the range 2–20 mHz mainly dominated by the so-called “diffusion impedance”, and the difference between the capacitance in the two feed solutions.