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Structure and Dynamics of Electric-Field-Driven Convective Flows at the Interface between Liquid Electrolytes and Ion-Selective Membranes

Alexander Warren, Arpita Sharma, Duhan Zhang, Gaojin Li, Lynden A. Archer

2021Langmuir10 citationsDOIOpen Access PDF

Abstract

≈ 20 kT/e, a space charge layer forms near ion-selective interfaces in liquid electrolytes. Interactions between the space charge and an imposed electric field drives a hydrodynamic instability known as electroconvection. Through particle tracking velocimetry we experimentally study the structure and dynamics of the resultant electroconvective flow. Consistent with previous numerical simulations, we report that, following imposition of a sufficiently large voltage, electroconvection develops gradually as pairs of counter-rotating vortices, which nucleate at the interface between an ion-selective substrate and a liquid electrolyte. Depending on the imposed voltage and cell geometry, the vorticies grow to length scales of hundreds of micrometers. Electroconvective flows are also reported to be structured and multiscale, with the size ratio of the largest to the smallest observable vortices inversely proportional to the Debye screening length.

Topics & Concepts

Electric fieldElectrolyteDebye lengthIonMechanicsChemical physicsChemistryElectrohydrodynamicsVortexInstabilitySpace chargeConvectionVoltageMolecular physicsMaterials sciencePhysicsElectronElectrodePhysical chemistryOrganic chemistryQuantum mechanicsMembrane-based Ion Separation TechniquesNanopore and Nanochannel Transport StudiesElectrostatics and Colloid Interactions
Structure and Dynamics of Electric-Field-Driven Convective Flows at the Interface between Liquid Electrolytes and Ion-Selective Membranes | Litcius