Electrogeneration of peroxodicarbonate anion: Synthesis of tetraalkylammonium silylcarboxylate

Oxygen electroreduction in the presence of CO₂ in acetonitrile solutions of tetraalkylammonium salts is a means to produce tetraalkylammonium peroxodicarboxylates. The latter react with triorganosilanes R₃SiH to yield tetraalkylammonium salts of triorganylsilylcarboxylic acids. Diorganylsilanes under the same conditions produce cyclic siloxanes exclusively.     

Hydrophobic hydration and hydrophobic interaction in tetraalkylammonium salt solutions: The cation size effect

The heats of solution of tetrahexylammonium and tetraheptylammonium bromides in water and aqueous solutions of formamide and hexamethylphosphoric triamide have been measured at 318 and 338 K. The standard enthalpies and heat capacities of solution and the enthalpic and heart capacity parameters of amide-electrolyte pair interaction have been determined. It has been confirmed that the standard heat capacities of solution and the amide-electrolyte interaction parameters as a function of the cation size pass through an extremum. The hydrophobic hydration effect is weaker for large tetraalkylammonium cations.     

Solubility of sodium soaps in aqueous salt solutions

The solubility of sodium soaps in dilute aqueous salt solutions has been systematically investigated by direct visual phase behavior observations. The added electrolytes, including simple inorganic salts and bulky organic salts, influence the solubility of sodium soaps in water, as represented by the varied soap Krafft point. Two inorganic salts, sodium chloride and sodium perchlorate, demonstrate a "salting-out" property. On the other hand, tetraalkylammonium bromides show an excellent ability to depress the soap Krafft point and enhance the soap solubility in water. With increasing the tetraalkylammonium ionic size, the degree of "salting-in" of soaps in water increases. However, solubility of pure tetraalkylammonium bromide in water decreases as the length of the alkyl chains increases. Furthermore, in the ternary water-tetrapentylammonium bromide (TPeAB)-sodium myristate (NaMy) system, we observed an upper cloud point phenomenon, which greatly shrinks the 1-phase micellar solution region in the phase diagram. This miscibility gap, together with the organic salt solubility limitation, restricts the use of tetraalkylammonium bromides with alkyl chains longer than 4 carbon atoms as effective soap solubility enhancement electrolytes. We also found that for sodium soap with a longer hydrocarbon chain, more tetrabutylammonium salt is required to reduce the soap Krafft point to room temperature.     

Thermochemistry of nonaqueous electrolyte solutions

Heats of solution and specific heats have been measured for NaI and KI in methanol at 25 and 50 for the full range of concentrations; the integral heat of solution of NaI or KI in methanol has a positive temperature coefficient, whereas the heats of solution of these salts and all strong electrolytes in water have negative temperature coefficients. The thermal capacity of an aqueous electrolyte is less than the sum of the thermal capacities of the components, whereas the result for methanol is the reverse. In addition, the integral heat of solution has a concentration coefficient much larger than that found for water, mainly because water has a dielectric constant about 2.5 times that of methanol. This leads to stronger interactions between ions in methanol, which contains ion pairs.     

Thermochemical study of the influence of tetraalkylammonium cation sizes on the interaction of their salts with formamide and carbamide in aqueous solutions

Solutions of tetrahexylammonium salts in mixtures of water with additives of hydrophilic substances formamide and carbamide were studied by the thermochemical method at 298.15 K. The enthalpies of solution of tetrahexylammonium perchlorate were measured by the sedimentation method, and the enthalpies of solution of tetrahexylammonium bromide were calculated. The enthalpic coefficients of pair interaction electrolyte—amide in an aqueous solution were determined. The data obtained were compared with those for te tramethyl- tetraethyl- and tetrabutylammonium salts to study the influence of the tetraalkylammonium cation size on its solvation and interaction with amides in an aqueous solution.     

Impregnation of Acetylene Black Electrodes with a Polytetrafluoroethylene Binder with an Aqueous Solution and Evaluation of Its Specific Double Layer Capacity

The effect of (0.05 M) tetraalkylammonium salt additions in aqueous 0.5 M KOH on the rate of impregnation of carbon black electrodes with a polytetrafluoroethylene binder (5–20 wt % PTFE) at hydrogen evolution potentials was studied. It was shown that tetraalkylammonium salts facilitate the fast filling of electrodes with electrolyte, and their effect increases with the molecular mass of the cation. Tetramethylammonium bromide showed the weakest effect. In solutions with tetrabutylammonium bromide, the electrodes were completely flooded with 5 wt % PTFE within 15 min. Diethyldibenzylammonium bromide had a similar effect. The influence of the PTFE concentration in the electrodes on their capacity was studied. The specific capacity of acetylene black in acid and alkaline aqueous solutions was evaluated from the electrode surface area determined by low-temperature nitrogen adsorption (BET).     

Nitroguanidine‐Fused Bicyclic Guanidinium Salts: A Family of High‐Density Energetic Materials

A series of nitroguanidine‐fused bicyclic guanidinium energetic salts paired with inorganic energetic anions, mono‐ and di‐tetrazolate anions were synthesized through simple metathesis reactions of 2‐iminium‐5‐nitriminooctahydroimidazo[4,5‐d]imidazole chloride and sulfate with the corresponding silver and barium salts, respectively, in aqueous solution. Key physical properties, such as melting point, thermal stability, and density were measured. The relationship between the structures of the salts and these properties was determined. The salts exhibit thermal stability and density (>1.60 g cm^?3) that are comparable to currently used explosives The structures of the nitrate salt 1 and the dinitrocyanomethanide salt 4 were confirmed by single‐crystal X‐ray analysis. Densities, heats of formation, detonation pressures and velocities, and specific impulses were calculated. All of the salts possess positive calculated heats of formation and most of them exhibit promising energetic performance that is comparable with those of 1,3,5‐trinitrobenzene (TNT), 1,3,5‐triamino‐2,4,6‐trinitrobenzene (TATB), and cyclotrimethylenetrinitramine (RDX). The effect of the fused bicycle 2‐iminium‐5‐nitriminooctahydroimidazo[4,5‐d]imidazole on these physicochemical properties was examined and discussed.     

Heat Capacity of Micellization of Lithium Perfluoroalkanoates in Aqueous Solution

Specific heats of aqueous solutions of lithium perfluoroalkanoates, from C₆ to C₉, were determined at 298.15 K at concentrations below and above the critical micelle concentration. Infinite dilution apparent molar heat capacities are compared with literature data for corresponding salts with different counterions. Heat capacities of micellization of these surfactants in water were calculated from the specific heat data and also by measurements of the heat of micellization at two temperatures, 298.15 K and 308.15 K. The data were treated under the assumption of the pseudo-phase separation model. The two series of data agree in the case of perfluorononanoate but diverge for perfluorosurfactants with shorter hydrophobic chains. The results are interpreted in terms of the extent of the applicability of the adopted chemical model. Heat capacities of the micellization process obtained from experimental specific heats compare well with literature values relative to the sodium salts of the examined anions.     

Spectroscopic study on anion recognition properties of calix[4]pyrroles: effects of tetraalkylammonium cations

The solution binding properties of calix[4]pyrroles with anion (added as tetraalkylammonium salts) were investigated using UV-vis spectroscopic techniques. The obvious red-shift of absorption maximum band of calix[4]pyrrole in EtOH in the presence of the tetramethylammonium (TMA(+)) or tetraethylammonium (TEA(+)) salts were observed. These results displayed in electronic absorption spectra indicated calix[4]pyrrole receptors linking anionic species through multiple hydrogen bonding interactions are capable of using the periphery electron-rich "walls" for selectively binding electron-deficient tetraalkylammonium cation subunits by cation-pi charge-transfer interaction. It was seen that the stability of the calix[4]pyrrole-anion complex depends strongly on the cation. The meso-alkyl groups of the calix[4]pyrrole, the affinity for the anion subunits and the structure of tetraalkylammonium cations have considerable effects on the formation of cation-pi charge-transfer interaction.     

A pulse polarographic investigation of parathion and some other nitro-containing pesticides

The polarographic behaviour of parathion, its major metabolites (paraoxon and p-nitrophenol), and of methylparathion, EPN and pentachloronitrobenzene has been studied over a wide pH range. Differential pulse polarography is used to differentiate between parathion, p-nitrophenol and pentachloronitrobenzene. An indirect determination of parathion in the presence of paraoxon can be based on their respective rates of hydrolysis in 0.5 M sodium hydroxide solution. The electrochemical behaviour of these compounds has also been investigated in solutions containing tetraalkylammonium salts as the supporting electrolyte.     

Quantitative NMR spectrometry of phase-transfer catalysts: Part 1. Determination of Extraction Constants and Water of Hydration

Proton magneticf resonance spectrometry was applied for evaluation of the distribution ratios and apparent extraction constants of tetraalkylammonium and tetraalkylphosphonium salts in two liquid-phase systems. Triethylbenzyl- and tetrabutylammonium chloride in dichloromethane and chlorobenzene, respectively, were shown to be salted out in the presence of aqueous sodium hydroxide solutions. ¹H-n.m.r. spectrometry was also used to determine the degree of hydration of quaternary onium salts in two-phase systems. The results were compatible with those obtained by the Karl Fischer method.     

Effects of charge separation, effective concentration, and aggregate formation on the phase transfer catalyzed alkylation of phenol

The factors that influence the rate of alkylation of phenol under phase transfer catalysis (PTC) have been investigated in detail. Six linear, symmetrical tetraalkylammonium cations, Me(4)N(+), Et(4)N(+), (n-Pr)(4)N(+), (n-Bu)(4)N(+), (n-Hex)(4)N(+), and (n-Oct)(4)N(+), were examined to compare the effects of cationic radius and lipophilicity on the rate of alkylation. Tetraalkylammonium phenoxide·phenol salts were prepared, and their intrinsic reactivity was determined from initial alkylation rates with n-butyl bromide in homogeneous solution. The catalytic activity of the same tetraalkylammonium phenoxides was determined under PTC conditions (under an extraction mechanism) employing quaternary ammonium bromide catalysts. In homogeneous solution the range in reactivity was small (6.8-fold) for Me(4)N(+) to (n-Oct)(4)N(+). In contrast, under PTC conditions a larger range in reactivity was observed (663-fold). The effective concentration of the tetraalkylammonium phenoxides in the organic phase was identified as the primary factor influencing catalyst activity. Additionally, titration of active phenoxide in the organic phase confirmed the presence of both phenol and potassium phenoxide aggregates with (n-Bu)(4)N(+), (n-Hex)(4)N(+), and (n-Oct)(4)N(+), each with a unique aggregate stoichiometry. The aggregate stoichiometry did not affect the PTC initial alkylation rates.     

Dynamic quartz crystal impedance measurements of polyvinylferrocene film deposition

Dynamic crystal impedance measurements were used to study the electrochemically-driven deposition of polyvinylferrocene (PVF) films from dichloromethane solutions of PVF onto Au electrodes of a quartz crystal microbalance. Under all the conditions studied, the PVF films were non-rigid, to an extent that depended upon several experimental factors. Films deposited from solutions containing perchlorate salts of tetraalkylammonium salts departed less from rigidity than those deposited under otherwise identical conditions from tetrafluoroborate media. In contrast, the use of different tetraalkylammonium cations, or the use of a potential sweep vs. a potential step from 0 V to the deposition potential (0.7 V), made no significant difference. The departure from rigid characteristics varied with coverage. For the interval of time during deposition that the coverage was 10–160 nmol cm⁻² (of monomeric ferrocene units), the films showed no additional departure from rigidity. On the basis that the upper figure corresponds closely to a “monolayer” of terminally attached chains of mean length, we attribute this behaviour to the presence of a dense film, within which chain motion is considerably restrained.     

Tetraalkylammonium Salts as Hydrogen‐Bonding Catalysts

Although the hydrogen‐bonding ability of the α hydrogen atoms on tetraalkylammonium salts is often discussed with respect to phase‐transfer catalysts, catalysis that utilizes the hydrogen‐bond‐donor properties of tetraalkylammonium salts remains unknown. Herein, we demonstrate hydrogen‐bonding catalysis with newly designed tetraalkylammonium salt catalysts in Mannich‐type reactions. The structure and the hydrogen‐bonding ability of the new ammonium salts were investigated by X‐ray diffraction analysis and NMR titration studies.     

Chromatographic and spectroscopic studies of the solvent properties of a new series of room-temperature liquid tetraalkylammonium sulfonates

Fifteen tetraalkylammonium salts of the functionalized sulfonic acids N,N-bis(2-hydroxy- ethyl)-2-aminoethanesulfonic acid, 2-(cyclohexylamino)ethanesulfonic acid and 2-hydroxy-4- morpholinopropanesulfonic acid were synthesized and the eight organic salts that were liquid at room temperature were characterized by physical, spectroscopic and chromatographic methods. All liquid salts were viscous at room temperature but after dilution with a suitable cosolvent could be used as mobile phases in liquid chromatography. For this application, the rapid deterioration of silica-based column packings was more of a deterrent than the physical properties of the salts. The tetraalkylammonium sulfonates had wide liquid ranges and were stable as column packings up to 150–180°C, making them suitable for use in gas chromatography. Their solvent properties were characterized by solvatochromic parameters [E_T(30), π*, α and β] and by thermodynamic parameters determined by gas chromatography. Good agreement was found between the predictions of the two methods. The liquid salts showed strong orientation and solvent hydrogen bond acceptor capacity with weak hydrogen bond donor capacity in spite of the functionalization of the anions. The most probable reason for the weak hydrogen bond donor capacity of the anions is the unavailability of these functional groups for solute interactions owing to their preferential involvement in the formation of anion association complexes. The chemically defined structure, unique solvent properties and wide usable temperature ranges make the tetraalkylammonium sulfonates useful stationary phases for gas chromatography.     

A Simple Preparation of Anhydrous Tetra Alkylammonium Salts

Tetraalkyl ammonium (TAA) salts are of great importance in many areas of chemistry (organic, physical etc.). Tetraalkylammonium (TAA) chlorides, bromides or iodides are usually prepared by direct quaternization of trial-kyl amines with the corresponding alkyl halides. However other tetraalkylammonium (TAA) salts - cyanides, rhoda-nides, azides etc. cannot be prepared in this direct way. A typical method of preparation of these salts consists in ion exchange between available TAA halides and various salts containing the required anions. In some instances simply treating the TAA halides with aqueous solution of silver salts can be applied. This procedure, however, besides being costly is limited to the cases when the required silver salts are soluble in water¹.     

Ion association in tetraalkylammonium pertechnetate solutions

The solubility of tetraalkylammonium pertechnetates in aqueous electrolyte solutions has been studied. It does not practically depend on ionic strength of the solution when specific interaction of own ions and ions of the dissolved electrolyte (e.g. LiNO₃ up to 5 mol/l) does not occur. A remarkable dependence of Bu₄NTcO₄ solubility on acidity of the solution has been found. The influence of ion association on the solubility is discussed.     

Apparent molal volumes and heat capacities of some alkali halides and tetraalkylammonium bromides in aqueoustert-butanol solutions

The densities and volumetric specific heats of hydrochloric acid, alkali chlorides and bromides, and tetraalkylammonium bromides were measured in 0 to 40% by weighttert-butanol (t-BuOH) in water with a flow densimeter and a flow microcalorimeter. The effect of salt concentration was investigated in the case of NaCl. The apparent molal volumes and heat capacities and the derived transfer functions of the electrolytes from water tot-BuOH-water mixtures can be interpreted through solute-solute pair and triplet interactions by analogy with the transfer functions oft-BuOH from water to electrolyte solutions, with the salting-in and salting-out effects, and with the influence of electrolytes on the thermodynamics of micellization. At lowt-BuOH concentrations, the transfer functions seem to be reflecting primarily electrolyte-nonelectrolyte pair interactions. At intermediatet-BuOH concentration, wheret-BuOH associates, the hydrophobic bonding is enhanced by hydrophilic ions through a salting-out effect on monomers and by hydrophobic salts through triplet interaction (mixed association complexes). The Me ₄ NBr and Et ₄ NBr are intermediate electrolytes which do not have much effect on thet-BuOH hydrophobic bonding. At hight-BuOH concentrations the transfer functions tend to the values they would have in puret-BuOH.     

Significance of a volcano relation of fajans for hydration energies

A volcano-shaped relation between heats of solution of a series of salts and the difference of hydration energy of the ions of the salt was noted by Fajans. This relation has a maximum when the difference of hydration energy of the cation and anion approaches zero. A rationalization of this type of relation is proposed on the basis of sums of reciprocal radii terms which represent the dependence of electrostatic hydration energy on ion size. The general trend of heats of solution with ionic size in series of salts with either a common cation or a common anion is discussed.