Influence of Tethered Ions on Electric Polarization and Electrorheological Property of Polymerized Ionic Liquids

He, Fang; Wang, Bo; Zhao, Jia; Zhao, Xiaopeng; Yin, Jianbo

doi:10.3390/molecules25122896

Cited by 16 publications

(11 citation statements)

References 35 publications

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“…16 In particular, for a polar molecular ERF, 17 although it has higher mechanical properties, the existence of polar molecules on the surface of the dispersed phase leads to an ERF with poor thermal stability and large leakage current density. 18 To solve this problem, some researchers have used intrinsically polarizable materials, 19 such as conductive polymers, [20][21][22][23] carbon nanotubes, 24,25 graphene oxide (GO), 26 and poly(ionic liquids), [27][28][29][30] to develop a variety of ERFs. But the low yield stress or large zerofield viscosity of these ERFs limits their practical applications.…”

Section: Introductionmentioning

confidence: 99%

Efficient and stable electrorheological fluids based on chestnut-like cobalt hydroxide coupled with surface-functionalized carbon dots

et al. 2022

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Section: Introductionmentioning

confidence: 99%

Efficient and stable electrorheological fluids based on chestnut-like cobalt hydroxide coupled with surface-functionalized carbon dots

et al. 2022

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“…We consider that this may be due to the fact that although the activation energy ( E a = E c + E el , as shown in Figure ) of ion dissociation and migration in iCOP-TFSI particles is low, the energy barrier of ions through the interface between particles and carrier liquid (Δ E = E a1 – E a , where E a1 is the activation energy (90.6 kJ/mol) of ion diffusion in the whole ER fluid, which is calculated by the dc conductivity ( σ dc ) of iCOP-TFSI ER fluid as a function of temperature with the Arrhenius equation σ dc ∝ e – E a1/ RT ) is relatively high as shown in Figure h. Figure shows that iCOP-TFSI has a larger Δ E (24.0 kJ/mol) and smaller E a (66.6 kJ/mol) than those (Δ E = 13.6 kJ/mol and E a = 70.53 kJ/mol) of linear D-PIL[TFSI] . This means that the iCOP structure enables the internal counterions to have easy dissociation and migration ability in the particles, while the cage covalent organic framework structure effectively limits the long-range migration of TFSI – from iCOP particles into carrier liquid.…”

Section: Resultsmentioning

confidence: 99%

“…Figure 6 shows that iCOP-TFSI has a larger ΔE (24.0 kJ/mol) and smaller E a (66.6 kJ/mol) than those (ΔE = 13.6 kJ/mol and E a = 70.53 kJ/mol) of linear D-PIL [TFSI]. 53 This means that the iCOP structure enables the internal counterions to have easy dissociation and migration ability in the particles, while the cage covalent organic framework structure effectively limits the long-range migration of TFSI − from iCOP particles into carrier liquid. Therefore, the iCOP-TFSI ER fluid shows very low leaking current density.…”

Section: ■ Introductionmentioning

confidence: 99%

A Water-Free Ionic Covalent Organic Polymer with High Electrorheological Activity and Temperature Stability

Xue

Zhao

et al. 2023

ACS Appl. Polym. Mater.

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Ionic polymers are important electrorheological (ER) materials, whose ER effect originates from ion motion-induced interfacial polarization. However, the first-generation ionic polymer ER material based on traditional polyelectrolyte needs adsorbed water to make ion movement to activate the ER effect. This results in poor temperature and cycling stability. Although the second-generation ionic polymer ER material based on polyethylene oxide-salt complexes and the currently developed poly(ionic liquid) ER material do not require adsorption of water to activate the ER effect due to decreased ion-pair dissociation energy, low glass transition temperature still limits their temperature and cycling stability. Herein, we report an ionic polymer ER material based on ionic covalent organic polymer (iCOP) synthesized via the Menshutkin reaction and ion exchange, which exhibits not only a highly anhydrous ER effect due to lots of hydrophobic fluoric counterion-induced strong interfacial polarization but also excellent temperature stability and cycling stability due to a unique covalent organic framework structure. In particular, its leaking current density and power consumption are far lower than those of the ER system of traditional polyelectrolytes, polyethylene oxide-salt complexes, and poly(ionic liquid)s. These make iCOP possess large potential as a platform to develop next-generation ionic polymer ER material with high performance.

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“…The size of cation and the interaction between anions will affect the conductivity of ILs and PILs [ 127 , 128 ]. In order to explore the effect of cations on the ER response of PILs, He et al [ 129 ] synthesized PILs with different tethered cations dimethyldiallylammonium ([DADMA] + ), benzylethyl trimethylammonium ([VBTMA] + ) and 1-vinyl 4-ethylimidazolium ([C2VIm] + ) and the same counter anion hexafluorophosphate (PF 6 − ). The chemical structures of the cations are shown in Figure 4 .…”

Section: Er Responsesmentioning

confidence: 99%

The Electric Field Responses of Inorganic Ionogels and Poly(ionic liquid)s

et al. 2020

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Ionic liquids (ILs) are a class of pure ions with melting points lower than 100 °C. They are getting more and more attention because of their high thermal stability, high ionic conductivity and dielectric properties. The unique dielectric properties aroused by the ion motion of ILs makes ILs-contained inorganics or organics responsive to electric field and have great application potential in smart electrorheological (ER) fluids which can be used as the electro-mechanical interface in engineering devices. In this review, we summarized the recent work of various kinds of ILs-contained inorganic ionogels and poly(ionic liquid)s (PILs) as ER materials including their synthesis methods, ER responses and dielectric analysis. The aim of this work is to highlight the advantage of ILs in the synthesis of dielectric materials and their effects in improving ER responses of the materials in a wide temperature range. It is expected to provide valuable suggestions for the development of ILs-contained inorganics and PILs as electric field responsive materials.

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Influence of Tethered Ions on Electric Polarization and Electrorheological Property of Polymerized Ionic Liquids

Cited by 16 publications

References 35 publications

Efficient and stable electrorheological fluids based on chestnut-like cobalt hydroxide coupled with surface-functionalized carbon dots

Efficient and stable electrorheological fluids based on chestnut-like cobalt hydroxide coupled with surface-functionalized carbon dots

A Water-Free Ionic Covalent Organic Polymer with High Electrorheological Activity and Temperature Stability

The Electric Field Responses of Inorganic Ionogels and Poly(ionic liquid)s

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