Polymerized ionic liquids on charged electrodes: New prospects for electrochemistry

Kalikin, Nikolai N.; Kolesnikov, A. L.; Budkov, Yu. A.

doi:10.1016/j.coelec.2022.101134

Cited by 7 publications

(7 citation statements)

References 47 publications

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“…One work 72 correctly notes that the number of electrochemical applications of ionic liquids and their polymerized forms is increasing, while PIL-based systems have almost no theoretical description (as well as IL-based systems, by the way). They offered a brief prospective overview of the current state of the art in this field (as of early 2022).…”

Section: Basic and Theoretical Aspects Of The Study Of Pilsmentioning

confidence: 99%

“…They offered a brief prospective overview of the current state of the art in this field (as of early 2022). 72 The study 73 developed a theoretical model that describes the behavior of a polymeric ionic liquid and its solution on a charged electrode. The model includes the conformational entropy of polymerized cations within the framework of Lifshitz theory and electrostatic and volume interactions of counterions in the mean-field approximation.…”

Section: Basic and Theoretical Aspects Of The Study Of Pilsmentioning

confidence: 99%

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Advanced research and prospects on polymer ionic liquids: trends, potential and application

Lebedeva,

Kultin,

Kustov

2023

Green Chem.

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Section: Basic and Theoretical Aspects Of The Study Of Pilsmentioning

confidence: 99%

Section: Basic and Theoretical Aspects Of The Study Of Pilsmentioning

confidence: 99%

Advanced research and prospects on polymer ionic liquids: trends, potential and application

Lebedeva,

Kultin,

Kustov

2023

Green Chem.

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“…In contrast, the oxime proton peak is almost unchanged in the complex spectrum, ruling out the participation of the oxime group in the complexation reaction. [47] On the other hand, the 13 C-NMR spectrum of LSOH revealed the presence of C-atoms characteristic of both lutidinium and salicylaldoxime fragments (Figure 1C). In particular, the two prominent peaks at δ of 161.00 and 154.14 ppm can be attributed to the nuclear resonances of phenolic (CÀ O) and azomethinic (À CH=N) carbon atoms, respectively.…”

Section: Structural Characterization Of Lsoh and Vo(lso)mentioning

confidence: 99%

“…Functionalized ionic liquids, also known as task‐specific ionic liquids (TSILs), have gained popularity in recent years because their composition may be tailored to meet the needs of certain applications in terms of the physical, chemical, and biological qualities they must exhibit [5] . They investigated their potential usefulness in several fields, such as organic synthesis, [6,7] nanomaterial's preparation, [8] catalysis, [9] oxidative desulfurization, [10] biological samples and metal ions extraction, [11,12] electrochemistry, [13] active pharmaceutical ingredients (API), [14] and so on [3] . Recently, we have designed and prepared TSILs capable of performing specific functions like scavenging heavy metal ions and primary amines from aqueous effluents [15–18] and chemical sensing [19,20] …”

Section: Introductionmentioning

confidence: 99%

Synthesis and Characterization of New Lutidinium Ionic Liquid‐Supported Vanadylsalicylaldoxime Complex for Catalytic Application in Epoxidation Reaction

Elshaarawy

Gawad

Hassan

et al. 2023

Chemistry & Biodiversity

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A new chelating task-specific ionic liquid (TSIL), lutidinium-based salicylaldoxime (LSOH), and its square pyramidal vanadyl(II) complex (VO(LSO) 2 ) have been successfully synthesized and structurally characterized using elemental (CHN), spectral, and thermal analyses. The catalytic activity of the lutidinium-salicylaldoxime complex (VO(LSO) 2 ) in the alkene epoxidation reactions was studied under various reaction conditions, such as solvent effect, alkene/oxidant molar ratio, pH, reaction temperature, reaction time, and the catalyst dose. The results demonstrated that the CHCl 3 solvent, 1 : 3 of the cyclohexene/H 2 O 2 ratio, pH 8, temperature of 340 K, and catalyst dose of 0.012 mmol are assigned as the optimum conditions for achieving maximum catalytic activity for VO(LSO) 2 . Moreover, the VO(LSO) 2 complex has the potential for application in the effective and selective epoxidation of alkenes. Notably, under optimal VO(LSO) 2 conditions, cyclic alkenes convert more efficiently to their corresponding epoxides than linear alkenes.

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“…Despite the success of describing the EDL structure of various ionic materials, the covalent bonding of one ionic species to polymeric backbones or cross-linked networks introduces new considerations. The EDL structure of polymerized ionic liquids (PILs) has been studied using the polyelectrolyte adsorption model and molecular dynamics (MD) simulations, which predict higher EDL capacitances of polymeric ions due to the surface absorption of charged polymer chains upon applying an electric potential. ,− Recently, Budkov et al proposed a self-consistent field theory for the local electrostatic potential of PILs on a charged electrode. Their finding suggests that the differential capacitance profile is strongly sensitive to the boundary condition for the local polymer concentration on the electrode. , When there is a short-range depletion of the polymer ions near the charged surfaces, the differential capacitance shows a camel-shaped curve with two strongly asymmetric peaks and a significantly decreased capacitance from the polymeric ions.…”

Section: Introductionmentioning

confidence: 99%

Ionoelastomers at Electrified Interfaces: Differential Electric Double-Layer Capacitances of Cross-Linked Polymeric Ions and Mobile Counterions

Shin,

Hayward

et al. 2023

Macromolecules

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Ionoelastomers (IEs), consisting solely of crosslinked networks of polymerized ionic liquids (PILs), have gained attention for use in various electrochemical applications due to their unique combination of the electrochemical properties of ionic liquids (ILs) and the solid-state elastic properties of the polymer networks. However, the structure of the electric double layer (EDL) of IEs at electrified surfaces is not well understood, especially when considering that one of the ionic species is covalently bound to the cross-linked polymer network. Herein, we investigate the differential EDL capacitances of cross-linked polymeric ions and counterions in IEs. A pair of IEs with opposite polarity are prepared; the polycationic IE with cross-linked imidazolium cations and free bis(trifluoromethyl sulfonyl)imide (TFSI) anions and the polyanionic IE with cross-linked sulfonimide anions and free 1-ethyl-3-methylimidazolium (EMIM) cations. By applying two electrodes with a large contrast in surface area, the EDL capacitances of the cross-linked polymeric ions and the mobile counterions can be decoupled. We find that the EDL capacitances of the fixed ions are lower than that of the counterions in both the polyanion and polycation IEs, resulting in a highly asymmetric capacitance response depending on the sign of the applied voltage. Without cross-linking, we observe similar EDL capacitances for polymeric ions and counterions, suggesting that the elastic energy of the cross-linked networks in IEs restricts the freedom of polymeric ions to rearrange at the electrified surfaces, thereby reducing the EDL capacitance.

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Polymerized ionic liquids on charged electrodes: New prospects for electrochemistry

Cited by 7 publications

References 47 publications

Advanced research and prospects on polymer ionic liquids: trends, potential and application

Advanced research and prospects on polymer ionic liquids: trends, potential and application

Synthesis and Characterization of New Lutidinium Ionic Liquid‐Supported Vanadylsalicylaldoxime Complex for Catalytic Application in Epoxidation Reaction

Ionoelastomers at Electrified Interfaces: Differential Electric Double-Layer Capacitances of Cross-Linked Polymeric Ions and Mobile Counterions

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