Anion Effects on the Solid/Ionic Liquid Interface and the Electrodeposition of Zinc

Liu, Zhen; Cui, Tong; Lu, Tianqi; Ghazvini, Maryam; Endres, Frank

doi:10.1021/acs.jpcc.6b07812

Cited by 67 publications

(67 citation statements)

References 43 publications

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“…Moreover, the configuration of the anions can also have an impact on the interfacial structure as was addressed, e.g., by Liu et al [ were investigated in contact with the Au (111) surface. AFS measurements under cathodic polarization revealed that the number of layers and force necessary for their punctuation increases systematically with anion size, and it was concluded that this is also the cause for differences in macroscopic electrowetting behavior [97].…”

Section: The Electrified Interfacementioning

confidence: 99%

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Atomic Force Spectroscopy on Ionic Liquids

2019

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Ionic liquids have become of significant relevance in chemistry, as they can serve as environmentally-friendly solvents, electrolytes, and lubricants with bespoke properties. In particular for electrochemical applications, an understanding of the interface structure between the ionic liquid and an electrified interface is needed to model and optimize the reactions taking place on the solid surface. As with ionic liquids, the interplay between electrostatic forces and steric effects leads to an intrinsic heterogeneity, as the structure of the ionic liquid above an electrified interface cannot be described by the classical electrical double layer model. Instead, a layered solvation layer is present with a structure that depends on the material combination of the ionic liquid and substrate. In order to experimentally monitor this structure, atomic force spectroscopy (AFS) has become the method of choice. By measuring the force acting on a sharp microfabricated tip while approaching the surface in an ionic liquid, it has become possible to map the solvation layers with sub-nanometer resolution. In this review, we provide an overview of the AFS studies on ionic liquids published in recent years that illustrate how the interface is formed and how it can be modified by applying electrical potential or by adding impurities and solvents.

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Section: The Electrified Interfacementioning

confidence: 99%

“…97]. In their work, ionic liquids having the same [EMIm] + cation but four different anions bis(trifluoromethylsulfonyl)imide[TFSI] …”

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confidence: 99%

Atomic Force Spectroscopy on Ionic Liquids

2019

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“…IL interfaces are particularly important for interface-controlled applications such as sensor [4,[16][17][18][19], lubrication [20][21][22], separation [4,19,[23][24][25][26][27][28][29], electrochemistry [4,19,[30][31][32][33][34][35][36][37][38][39] and electronics [40][41][42] technologies. ILs further stimulated completely new concepts for catalysis [1,4,[43][44][45][46][47][48][49][50][51][52][53][54][55][56][57].…”

Section: Introductionmentioning

confidence: 99%

Ultrathin ionic liquid films on metal surfaces: adsorption, growth, stability and exchange phenomena

Lexow

Maier

Steinrück

2020

Advances in Physics: X

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The interface of ionic liquids (ILs) with solid surfaces is of pivotal interest for many applications, ranging from sensors, lubrication, separation technology, and electronics to electrochemistry and catalysis. We present a short review on ultrathin layers of ionic liquids on metal surfaces using a surface science approach. We mainly focus on specific examples of imidazolium-based ionic liquids on Ag(111) and Au(111) studied by angle-resolved X-ray photoelectron spectroscopy, and relate the obtained results to existing literature. We address a variety of phenomena on the molecular level, namely, (i) the adsorption, growth and wetting behavior of ILs, (ii) the thermal stability and desorption of ILs, (iii) exchange processes of anions and cations at the IL/solid interface, and (iv) the replacement of ILs from the IL/solid interface by porphyrins.

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“…[29] For metal-ion speciation in ILs (or DESs), we refer to ac ritical review by Estager et al and to other relevant articles that are available in the literature. [30][31][32][33][34] The influence of ligands on the asymmetric cleavage and on the nature of the coordination and the number of coordination sites is still required forad etailed understandingo fL CCs. For instance, complexes formed from AlCl 3 and neutral ligands ( 4-propylpyridine or N-butylpyrrolidine) are different upon varying the concentration of AlCl 3 in the mixtures.…”

Section: In [Emim]mentioning

confidence: 99%

“…Corresponding to this bending of the hysteresis curve at high inductions, ar apid increase in high inductionl osses is also found. [32] The bending of the hysteresis curve as well as the high induction losses are controlled by domain-wall nucleation and annihilation processes as well as by rotationo fm agnetic moments. [72][73][74][75] Reasonsf or the in- crease of high induction losses are the presence of non-magnetic pores or non-magnetic inclusions like iron oxidesi nt he deposited material as well as unfavorable orientations of the grains misaligned to the magnetic easy axis.…”

Section: Electrochemical Investigations and Characterization Of The Mmentioning

confidence: 99%

How a Transition‐Metal(II) Chloride Interacts with a Eutectic AlCl₃‐Based Ionic Liquid: Insights into the Speciation of the Electrolyte and Electrodeposition of Magnetic Materials

Pulletikurthi

Weidenfeller

Borodin

et al. 2017

Chemistry An Asian Journal

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Electrostatic interactions are characteristic of ionic liquids (ILs) and play a pivotal role in determining the formation of species when solutes are dissolved in them. The formation of new species/complexes has been investigated for certain ILs. However, such investigations have not yet focused on eutectic liquids, which are a promising class of ILs. These liquids (or liquid coordination complexes, LCCs) are rather new and are composed of cationic and anionic chloro complexes of metals. To date, these liquids have been employed as electrolytes to deposit metals and as solvents for catalysis. The present study deals with a liquid that is prepared by mixing a 1.2:1 mol ratio of AlCl and 1-butylpyrrolidine. An attempt has been made to understand the interactions of FeCl with the organic molecule using spectroscopy. It was found that dissolved Fe(II) species interact mainly with the IL anion and such interactions can lead to changes in the cation of the electrolyte. Furthermore, the viability of depositing thick magnetic films of Fe and Fe-Al has been explored.

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Anion Effects on the Solid/Ionic Liquid Interface and the Electrodeposition of Zinc

Cited by 67 publications

References 43 publications

Atomic Force Spectroscopy on Ionic Liquids

Atomic Force Spectroscopy on Ionic Liquids

Ultrathin ionic liquid films on metal surfaces: adsorption, growth, stability and exchange phenomena

How a Transition‐Metal(II) Chloride Interacts with a Eutectic AlCl₃‐Based Ionic Liquid: Insights into the Speciation of the Electrolyte and Electrodeposition of Magnetic Materials

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Anion Effects on the Solid/Ionic Liquid Interface and the Electrodeposition of Zinc

Cited by 67 publications

References 43 publications

Atomic Force Spectroscopy on Ionic Liquids

Atomic Force Spectroscopy on Ionic Liquids

Ultrathin ionic liquid films on metal surfaces: adsorption, growth, stability and exchange phenomena

How a Transition‐Metal(II) Chloride Interacts with a Eutectic AlCl3‐Based Ionic Liquid: Insights into the Speciation of the Electrolyte and Electrodeposition of Magnetic Materials

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How a Transition‐Metal(II) Chloride Interacts with a Eutectic AlCl₃‐Based Ionic Liquid: Insights into the Speciation of the Electrolyte and Electrodeposition of Magnetic Materials