Femtosecond Electron Solvation at the Ionic Liquid/Metal Electrode Interface

Muller, Eric A.; Strader, Matthew L.; Johns, James E.; Yang, Aram; Caplins, Benjamin W.; Shearer, Alex J.; Suich, David E.; Harris, Charles B.

doi:10.1021/ja3108593

Cited by 27 publications

(36 citation statements)

References 71 publications

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“…Such an evolution from dispersive to nondispersive behavior cannot be observed in IPS on metal surfaces [11] and is related to the molecules. The observation can be explained by electron localization [12][13][14][15][16][17][18]26]. Similar temporal change in the band structure is found for the 1 ML sample.…”

mentioning

confidence: 57%

“…Similar to charges in adsorbate's unoccupied states, electrons in IPS are subject to electron-vibrational interactions and the dielectric environment originated from the adsorbates. These interactions can lead to dynamic localization of the IPS, which has been studied by TR-ARPES in systems such as alkanes and polar solvents on metal surfaces [13][14][15][16], ionic liquids [17], and ionic crystals [18]. Recently, TR-ARPES has been used to study 2-D states at organic/metal interfaces [19][20][21] and organic semiconductor surfaces [22][23][24][25].…”

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confidence: 99%

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From two-dimensional electron gas to localized charge: Dynamics of polaron formation in organic semiconductors

et al. 2015

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Electronic transport in organic semiconductors is mediated by localized polarons. However, the dynamics on how delocalized electrons collapse into polarons through electron-nuclear interaction is not well-known. In this work, we use time and angle resolved photoemission spectroscopy (TR-ARPES) to study polaron formation in titanyl phthalocyanine deposited on Au(111) surfaces. Electrons are optically excited from the metal to the organic layer via the image potential state, which evolves from a dispersive to a non-dispersive state after photoexcitation. The spatial size of the electrons is determined from the band-structure using a tight-binding model. It is observed that the two-dimensional electron wave collapses into a wave packet of size ~ 3 nm within 100 fs after photoexcitation.

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confidence: 57%

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confidence: 99%

From two-dimensional electron gas to localized charge: Dynamics of polaron formation in organic semiconductors

et al. 2015

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“…In comparison with traditional molecular solvents, ILs have many unique physical properties such as negligible vapor pressure, large liquidus range, high thermal stability, and wide electrochemical window (Galinski et al, 2006 ; Andriyko et al, 2009 ). Functionalized ILs/task-specific ILs have already become general pattern to prepare new ionic liquid materials based on the remarkable “design” capacity of ILs (Muller et al, 2013 ). The design processes of novel materials sorely depend on empirical rules.…”

Section: Introductionmentioning

confidence: 99%

Viscosity, Conductivity, and Electrochemical Property of Dicyanamide Ionic Liquids

et al. 2018

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The instructive structure-property relationships of ionic liquids (ILs) can be put to task-specific design of new functionalized ILs. The dicyanamide (DCA) ILs are typical CHN type ILs which are halogen free, chemical stable, low-viscous, and fuel-rich. The transport properties of DCA ionic liquids are significant for their applications as solvents, electrolytes, and hypergolic propellants. This work systematically investigates several important transport properties of four DCA ILs ([C4mim][N(CN)2], [C4m2im][N(CN)2], N4442[N(CN)2], and N8444[N(CN)2]) including viscosity, conductivity, and electrochemical property at different temperatures. The melting points, temperature-dependent viscosities and conductivities reveal the structure-activity relationship of four DCA ILs. From the Walden plots, the imidazolium cations exhibit stronger cation–anion attraction than the ammonium cations. DCA ILs have relatively high values of electrochemical windows (EWs), which indicates that the DCA ILs are potential candidates for electrolytes in electrochemical applications. The cyclic voltammograms of Eu(III) in these DCA ILs at GC working electrode at various temperatures 303–333 K consists of quasi-reversible waves. The electrochemical properties of the DCA ILs are also dominated by the cationic structures. The current intensity (ip), the diffusion coefficients (Do), the charge transfer rate constants (ks) of Eu(III) in DCA ILs all increased with the molar conductivities increased. The cationic structure-transport property relationships of DCA ILs were constructed for designing novel functionalized ILs to fulfill specific demands.

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“…Our studies and others have shown that the capacitance of IL/electrode interface is potential dependent, and the adsorption of gas on the IL/electrode interface will decrease the double-layer capacitance under a specific DC bias potential [80]. In contrast to the EDL typically observed in dilute aqueous or nonaqueous electrolytes, the ions of ILs are strongly oriented near the electrode into an ordered layer structure with local ion density at maximum possible value [81,82]. Multiple ion pair layers form at the interface of IL and metal electrode.…”

Section: Charging Current In CVmentioning

confidence: 63%

Electrode–Electrolyte Interfacial Processes in Ionic Liquids and Sensor Applications

Zeng

Wang

Rehman

2015

Electrochemistry in Ionic Liquids

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Femtosecond Electron Solvation at the Ionic Liquid/Metal Electrode Interface

Cited by 27 publications

References 71 publications

From two-dimensional electron gas to localized charge: Dynamics of polaron formation in organic semiconductors

From two-dimensional electron gas to localized charge: Dynamics of polaron formation in organic semiconductors

Viscosity, Conductivity, and Electrochemical Property of Dicyanamide Ionic Liquids

Electrode–Electrolyte Interfacial Processes in Ionic Liquids and Sensor Applications

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