Tetraalkylammonium salt

Small amounts of propionitrile and bis(cyanoethyl) ether are formed as by-products. The hydrogen ions are formed from water at the anode and pass to the cathode through a membrane. The catholyte that is continuously recirculated in the cell consists of a mixture of acrylonitrile, water, and a tetraalkylammonium salt the anolyte is recirculated aqueous sulfuric acid. A quantity of catholyte is continuously removed for recovery of adiponitrile and unreacted acrylonitrile the latter is fed back to the catholyte with fresh acrylonitrile. Oxygen that is produced at the anodes is vented and water is added to the circulating anolyte to replace the water that is lost through electrolysis. The operating temperature of the cell is ca 50—60°C. Current densities are 0.25-1.5 A/cm (see Electrochemical processing). 

The lanthanides form many compounds with organic ligands. Some of these compounds ate water-soluble, others oil-soluble. Water-soluble compounds have been used extensively for rare-earth separation by ion exchange (qv), for example, complexes form with citric acid, ethylenediaminetetraacetic acid (EDTA), and hydroxyethylethylenediaminetriacetic acid (HEEDTA) (see Chelating agents). The complex formation is pH-dependent. Oil-soluble compounds ate used extensively in the industrial separation of rate earths by tiquid—tiquid extraction. The preferred extractants ate catboxyhc acids, otganophosphoms acids and esters, and tetraaLkylammonium salts. 

This method is based on the generation of the tetraalkylammonium salt of pyrrolidorle, which acts as a base. The method is compatible with a large variety of carboxylic acids and alkylating agents. The method is effective for the preparation of macrolides. 

A/-Phenyl, 449 A/,A/ -Diisopropyl, 450 Phenyl Group, 450 Tetraalkylammonium salts, 451... 

In a rather nontraditional approach to acid protection, the tetraalkylammonium salts of amino acids allow for coupling of HOBt-activated amino acids in yields of 55-84%. ... 

In some cases only the first step is required, as with the formation of ethylam-monium nitrate. In many cases the desired cation is commercially available at reasonable cost, most commonly as a halide salt, thus requiring only the anion exchange reaction. Examples of these are the symmetrical tetraalkylammonium salts and trialkylsulfonium iodide. 

Table 3.1-4 Effects of cation symmetry on the melting points of isomeric tetraalkylammonium salts. In each case the cation (designated [N op] ) has four linear alkyl substituents, together containing a total of 20 carbons. Salts that are liquid at room temperature are indicated by /.

Table 3.5-1 lists the E-r values for the allcylammonium thiocyanates and nitrates and the substituted imidazolium salts. It can be seen that the values are dominated by the nature of the cation. For instance, values for monoallcylammonium nitrates and thiocyanates are ca. 0.95-1.01, whereas the two tetraalkylammonium salts have values of ca. 0.42-0.46. The substituted imidazolium salts lie between these two extremes, with those with a proton at the 2-position of the ring having higher values than those with this position methylated. This is entirely consistent with the expected hydrogen bond donor properties of these cations. 

Here, the relative stability of the anion radical confers to the cleavage process a special character. Thus, at a mercury cathode and in organic solvents in the presence of tetraalkylammonium salts, the mechanism is expected16 to be an ECE one in protic media or in the presence of an efficient proton donor, but of EEC type in aprotic solvents. In such a case, simple electron-transfer reactions 9 and 10 have to be associated chemical reactions and other electron transfers (at the level of the first step). Those reactions are shown below in detail ... 

This reaction is illustrative of a general procedure for the alkylation of active methylene functions in the presence of concentrated aqueous alkali catalyzed by tetraalkylammonium salts. This catalytic method has been used to alkylate arylacetonitriles with monohaloalkanes,2 dihaloalkanes,3 a-chloroethers,4 chloronitriles,.5 haloacetic acid esters,6 and halonitro aromatic compounds.7 It has also been used to alkylate ketones,8 lf/ indene,9 9i/-fluorene,ll) and the Reissert compound.11 The reaction is inhibited by alcohols and by iodide ion.2... 

In the halide-assisted method,25 a glycosyl halide (normally bromide) with a nonparticipating 2-substituent and with the thermodynamically more stable axial orientation at C-l is treated with an excess of the corresponding halide anion by the addition of a soluble tetraalkylammonium salt. This sets up an equilibrium between the axial and the (much less stable) equatorial glycosyl halide. The lat-... 

The reduction of aromatic sulphoxides into the corresponding thioethers appears to be general it occurs at a lead cathode, in alcoholic sulphuric acid solution and also in the presence of tetraalkylammonium salts - Data in DMF are also available, when phenol is used as a proton donor. 

The reaction can be used for making either chlorides or bromides by using the appropriate tetraalkylammonium salt as a halide source. 

Several modified reaction conditions have been developed. One involves addition of silver salts, which activate the halide toward displacement.134 Use of sodium bicarbonate or sodium carbonate in the presence of a phase transfer catalyst permits Reactions involving especially mild conditions to be used for many systems.135 Tetraalkylammonium salts... 

When applied versus a glass indicator electrode the potassium salt can better be replaced by a tetraalkylammonium salt like (C2H5)4NC104. 

Tetraalkylammonium salts, e.g. R4N I , are known, on treatment with moist silver oxide, AgOH, to yield basic solutions comparable in strength with the mineral alkalis. This is readily understandable for the base so obtained, R4N eOH, is bound to be completely ionised as there is no possibility, as with tertiary amines, etc.,... 

Ito et al.40 examined the electrochemical reduction of C02 in dimethylsulfoxide (DMSO) with tetraalkylammonium salts at Pb, In, Zn, and Sn under high C02 pressures. At a Pb electrode, the main product was oxalic acid with additional products such as tartaric, malonic, glycolic, propionic, and n-butyric acids, while at In, Zn, and Sn electrodes, the yields of these products were very low (Table 3), and carbon monoxide was verified to be the main product even at a Pt electrode, CO was mainly produced in nonaqueous solvents such as acetonitrile and DMF.41 Also, the products in propylene carbonate42 were oxalic acid at Pb, CO at Sn and In, and substantial amounts of oxalic acid, glyoxylic acid, and CO at Zn, indicating again that the reduction products of C02 depend on the electrode materials used. 

The first catalysts reported for the electroreduction of C02 were metallophthalocyanines (M-Pc).126 In aqueous solutions of tetraalkylammonium salts, current-potential curves at a cobalt phthalocyanine (Co-Pc)-coated graphite electrode showed a reduction current peak whose height was proportional to the C02 concentration and to the square root of the potential sweep rate at a given C02 concentration. On electrolysis, oxalic acid and glycolic acid were detected, but formic acid was not. Mn and Pd phthalocyanines were inactive, while Cu and Fe phthalocyanines were slightly active. At the potentials used for C02 reduction, M-Pc catalysts would be in their dinegative state, and the occupied dz2 orbital of the metal ion in the metallophthalocyanine was suggested to play an important role in the catalytic activity. 

This procedure works well for tetraalkylammonium salts of nickel and platinum complexes, e.g.,... 

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