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Room temperature ionic liquid reference electrodes

Room Temperature Ionic Liquid Reference Electrodes... [Pg.201]

Reference Electrodes for Use in Room-temperature Ionic Liquids... [Pg.296]

Voltammetric, electrodeposition, electrosynthetic and electroanalytical studies are carried out in room-temperature ionic liquids (RTILs) by a significant and increasing number of both industrial and academic laboratories [23-25], Such studies, when carried out at anything other than a very empirical level, require the use of a reference electrode . The purpose of this chapter is to address the special problems this poses and their solutions. First, however, we start by considering the essential features of a reference electrode in general. [Pg.296]

Silvester DS, Ward KR, Aldous L, Hardacre C, Compton RG (2008a) The electrochemical oxidation of hydrogen at activated platinum electrodes in room temperature ionic liquids as solvents. J Electroanal Chem 618 53-60 Silvester DS, Rogers El, Compton RG, McKenzie KJ, Ryder KS, Endres F, MacFarlane D, Abbott AP (2008b) Reference electrodes for use in room-temperature ionic liquids. In Endres F, MacFarlane DR, Abbot A (eds) Electrodeposition from ionic liquids. Wiley, Weinheim, pp 296-309... [Pg.129]

Occasionally also the use of so-caUed pseudo reference electrodes has been reported (see Chap. 14). Such pseudo reference electrodes became popular in polarography but especially in cyclic voltammetry, employing three electrode arrangements. They consist of a silver or platinum wire or activated carlxMi dipping into the electrolyte. They substitute for a reference electrode. Such electrodes were reported to exhibit very stable potentials. The ease of such an arrangement was also used in electrochemical studies in (room temperature) ionic liquids. It must be pointed out that electrode potentials versus such electrodes are meaningless as such arrangements do not constitute thermodynamic values. [Pg.29]

In this book, there are other chapters related to nonaqueous systems. Chapter 1 by Inzelt is on the electrode potentials and includes a section on the problem to relate the electrode potentials between different media. Chapter 2 by Gritzner is on the reference redox systems in nonaqueous systems and their relation to water. Chapter 3 by Tsirlina is on the liquid junction potential and somewhat deals with the problem between different solvents. Chapter 7 by Bhatt and Snook is on the reference electrodes for room temperature ionic liquids. See these chapters as well. [Pg.145]

Experimental techniques for handling high temperature molten salts have been developed for many more years than those for room temperature ionic liquids. Considerable experimental challenges need to be overcome to find a stable reference electrode that will survive high temperatures (often up to 1,000 °C) and highly corrosive molten salt environments. [Pg.212]

Snook GA, Bond AM (2010) Reference electrodes for electrochemical studies in room temperature ionic liquids. In Torriero AAJ, Shidthky MIA (eds) Electrochemical properties and applications of ionic liquids. Nova, New York... [Pg.228]

Molten salts or ionic liquids (also referred to as fused salts by some authors) were among the very first media to be employed for electrochemistry. In fact, Sir Humphrey Davy describes electrochemical experiments with molten caustic potash (KOH) and caustic soda (NaOH) [1] as early as 1802 A wide variety of single molten salts and molten salt mixtures have been used as solvents for electroanalytical chemistry. These melts run the gamut from those that are liquid well below room temperature to those melting at more than 2000°C. The former present relatively few experimental challenges, whereas the latter can present enormous difficulties. For example, commercially available Teflon- and Kel-F-shrouded disk electrodes and Pyrex glass cells may be perfectly adequate for electrochemical measurements in ambient temperature melts such as the room-temperature chloroaluminates, but completely inadequate for use with molten sodium fluoroaluminate or cryolite (mp = 1010°C), which is the primary solvent used in the Hall-Heroult process for aluminum electrowinning. [Pg.511]

Fig. 4.13 Cyclic voltammograms of (a) urea/ChCl, (b) ethylene gly-col/ChCl and (c) malonic acid/ChCl ionic liquids. Voltammograms were acquired at room temperature (20°C), using a Pt disk (2 mm diameter) working electrode, a Ag wire reference electrode and a potential scan rate of50mVs 1. Fig. 4.13 Cyclic voltammograms of (a) urea/ChCl, (b) ethylene gly-col/ChCl and (c) malonic acid/ChCl ionic liquids. Voltammograms were acquired at room temperature (20°C), using a Pt disk (2 mm diameter) working electrode, a Ag wire reference electrode and a potential scan rate of50mVs 1.
The redox reaction between iodides, I and I3, is also used as the reference electrodes in nonchloroaluminate ionic liquids especially for the N(CF3S02)2 ionic liquids. Platinum wire is used for the electrode and immersed in an ionic liquid that contains iodine and an iodide salt having the same cation as the ionic liquid. The concentration ratio of the iodine salt to iodide is often specified as 1 4, namely [I3 ] [I ] = 1 3. The potential of this l /l3 electrode is reported as —0.16 V in TMHAN(CF3S02)2 at 50°C [15] (TMHA = trimethyl-n-hexylam-monium) and —0.21 V in EM1N(CF3S02)2 at room-temperature [16] against Fc/Fc. ... [Pg.33]


See other pages where Room temperature ionic liquid reference electrodes is mentioned: [Pg.137]    [Pg.32]    [Pg.97]    [Pg.64]    [Pg.28]    [Pg.192]    [Pg.353]    [Pg.72]    [Pg.109]    [Pg.361]    [Pg.304]    [Pg.32]    [Pg.500]    [Pg.2]   
See also in sourсe #XX -- [ Pg.38 , Pg.39 ]




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Reference Electrodes for Use in Room-temperature Ionic Liquids

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