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Bipolar Membrane and Water Splitting in Electrodialysis

Ireneusz Miesia̧c, Beata Rukowicz

2021Electrocatalysis22 citationsDOIOpen Access PDF

Abstract

Abstract The traditional view of the conductivity of electrolytes is based on the mobility of ions in an electric field. A new concept of water conductivity introduces an electron–hole mechanism known from semiconductor theory. The electrolyte ions in the hydrogen bond network of water imitate the structure of a doped silicon lattice. The source of the current carriers is the electrode reaction generating H + and OH − ions. The continuity of current flow is provided through the electron–hole mechanism, and the movement of electrolyte ions is only a side process. Bipolar membrane in the semiconductor approach is an electrochemical diode forward biased. Generation of large amounts of H + and OH − has to be considered as a result of current flow and does not require any increase in the water dissociation rate. Bipolar membranes are essential in electrodialysis stacks for the recovery of acids and bases by salt splitting. Graphic Abstract

Topics & Concepts

ElectrodialysisElectrolyteWater splittingDissociation (chemistry)ChemistrySemiconductorElectrochemistryIonMembraneConductivityChemical physicsDiodeInorganic chemistryElectrodeMaterials scienceCatalysisOptoelectronicsPhysical chemistryOrganic chemistryBiochemistryPhotocatalysisMembrane-based Ion Separation TechniquesFuel Cells and Related MaterialsMembrane Separation Technologies
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