Unknown

Dataset Information

0

Influence of the Electrolyte Film Thickness on Charge Dynamics of Ionic Liquids in Ionic Electroactive Devices.

ABSTRACT: Developing advanced ionic electroactive devices such as ionic actuators and supercapacitors requires the understanding of ionic diffusion and drifting processes, which depend on the distances over which the ions travel, in these systems. The charge dynamics of [C(4)mim][PF(6)] ionic liquid films and Aquivion membranes with 40 wt% [C(2)mim][TfO] were investigated over a broad film thickness (d) range. It was found that the double layer charging time ?(DL) follows the classic model ?(DL) = ?(D)d/(2D) very well, where D is the diffusion coefficient and ?(D) the Debye length. In the longer time regimes (t ? ?(DL)) where diffusion dominates, the charge dynamics become voltage dependent. For low applied voltage, the later stage charge process seems to follow the d(2) dependence. However, at high voltages (> 0.5 V) in which significant device responses occur, the charging process does not show d(2) dependence so that ?(diff) = d(2)/(4D), corresponding to the ion diffusion from the bulk region, was not observed.

SUBMITTER: Lin J 

PROVIDER: S-EPMC3298447 | biostudies-literature | 2012 Feb

REPOSITORIES: biostudies-literature

Json Xml
altmetric image

Publications

Influence of the Electrolyte Film Thickness on Charge Dynamics of Ionic Liquids in Ionic Electroactive Devices.

Lin Junhong J   Liu Yang Y   Zhang Q M QM  

Macromolecules 20120201 4

Developing advanced ionic electroactive devices such as ionic actuators and supercapacitors requires the understanding of ionic diffusion and drifting processes, which depend on the distances over which the ions travel, in these systems. The charge dynamics of [C(4)mim][PF(6)] ionic liquid films and Aquivion membranes with 40 wt% [C(2)mim][TfO] were investigated over a broad film thickness (d) range. It was found that the double layer charging time τ(DL) follows the classic model τ(DL) = λ(D)d/(  ...[more]

Similar Datasets

Unknown Ionic liquids behave as dilute electrolyte solutions.
| S-EPMC3683794 | biostudies-literature
Unknown Polarizable molecular dynamics simulations of ionic liquids: Influence of temperature control.
| S-EPMC7610910 | biostudies-literature
Unknown Structure-Property Relationship of Polymerized Ionic Liquids for Solid-State Electrolyte Membranes.
| S-EPMC7961940 | biostudies-literature
Unknown Using FT-IR spectroscopy to measure charge organization in ionic liquids.
| S-EPMC3813306 | biostudies-literature
Transcriptomics Transcriptional toxicity of imidazolium- and cholinium-based ionic liquids
2021-08-13 | GSE156769 | GEO
Unknown Virucidal Influence of Ionic Liquids on Phages P100 and MS2.
| S-EPMC5573800 | biostudies-literature
Unknown Hydrogen Bonding as a Clustering Agent in Protic Ionic Liquids: Like-Charge vs Opposite-Charge Dimer Formation.
| S-EPMC6645488 | biostudies-literature
Unknown Mass and charge transport in 1-alkyl-3-methylimidazolium triflate ionic liquids.
| S-EPMC3862598 | biostudies-other
Unknown Use of Ionic Liquids and Co-Solvents for Synthesis of Thin-Film Composite Membranes.
| S-EPMC8073406 | biostudies-literature
Unknown Electrolyte Tuning in Iron(II)-Based Dye-Sensitized Solar Cells: Different Ionic Liquids and I2 Concentrations.
| S-EPMC8200003 | biostudies-literature