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Molecular Dynamics of PEDOT:PSS Treated with Ionic Liquids. Origin of Anion Dependence Leading to Cation Design Principles

Ambroise de Izarra, Changwon Choi, Yun Hee Jang, Yves Lansac

2021The Journal of Physical Chemistry B29 citationsDOI

Abstract

Conductivity enhancement of PEDOT:PSS via the morphological change of PEDOT-rich domains has been achieved by introducing a 1-ethyl-3-methylimidazolium (EMIM)-based ionic liquid (IL) into its aqueous solution, and the degree of such change varies drastically with the anion coupled to the EMIM cation constituting the IL. We carry out a series of molecular dynamics simulations on various simple model systems for the extremely complex mixtures of PEDOT:PSS and EMIM:X IL in water, varying the anion X, the IL concentration, the oligomer model of PEDOT:PSS, and the size of the model systems. The common characteristic found in all simulations is that although planar hydrophobic anions X are the most efficient for ion exchange between PEDOT:PSS and EMIM:X, they tend to bring together planar EMIM cations to PEDOT-rich domains, disrupting PEDOT π-stacks with PEDOT-X-EMIM intercalating layers. Nonplanar hydrophobic anions, which leave most of EMIM cations in water, are efficient for both ion exchange and the formation of extended PEDOT π-stacks, as observed in experiments. Based on such findings, we propose a design principle for new cations replacing EMIM; nonplanar hydrophilic cations combined with hydrophobic anions should improve IL efficiency for PEDOT:PSS treatment.

Topics & Concepts

PEDOT:PSSIonic liquidMolecular dynamicsIonAqueous solutionChemical physicsMaterials scienceOligomerIonic bondingIon exchangeChemical engineeringChemistryPhysical chemistryComputational chemistryPolymer chemistryNanotechnologyOrganic chemistryLayer (electronics)CatalysisEngineeringIonic liquids properties and applicationsConducting polymers and applicationsAdvanced Battery Materials and Technologies