Palladium ions, reactions

It was found that sorbed palladium might catalyse reaction of Mn(III) reduction by Cf not only after it s removing from coal, but AC with palladium, Pd/AC, has also his own catalytic effect. On the base of dependence between characteristics of AC, chemical state of palladium on AC surface and catalytic action of Pd/AC in indicator reaction it might establish, that catalytic action concerns only to non-reduced or partly reduced palladium ions connected with chloride ions on coal surface. The presence or absence of catalytic action of Pd/AC in above-mentioned reaction may be proposed for determination of chemical state of palladium on AC surface. Catalytic effect was also used for palladium micro-amounts determination by soi ption-catalytic method. 

The reaction is highly exothermic as one might expect for an oxidation reaction. The mechanism is shown in Figure 15.1. Palladium chloride is the catalyst, which occurs as the tetrachloropalladate in solution, the resting state of the catalyst. Two chloride ions are replaced by water and ethene. Then the key-step occurs, the attack of a second water molecule (or hydroxide) to the ethene molecule activated towards a nucleophilic attack by co-ordination to the electrophilic palladium ion. The nucleophilic attack of a nucleophile on an alkene coordinated to palladium is typical of Wacker type reactions. 

The polymer resulting from oxidation of 3,5-dimethyl aniline with palladium was also studied by transmission electron microscopy (Mallick et al. 2005). As it turned out, the polymer was formed in nanofibers. During oxidative polymerization, palladium ions were reduced and formed palladium metal. The generated metal was uniformly dispersed between the polymer nanofibers as nanoparticles of 2 mm size. So, Mallick et al. (2005) achieved a polymer- metal intimate composite material. This work should be juxtaposed to an observation by Newman and Blanchard (2006) that reaction between 4-aminophenol and hydrogen tetrachloroaurate leads to polyaniline (bearing hydroxyl groups) and metallic gold as nanoparticles. Such metal nanoparticles can well be of importance in the field of sensors, catalysis, and electronics with improved performance. 

The details of the organic chemistry of the reaction of ethylene with PdCl2 (equation (1) above) are also known and are shown in Fig. 9.2. The palladium ion complexes with ethylene and water molecules and the water adds across the bond while still complexed to palladium. The palladium then serves as a hydrogen acceptor while the double bond reforms. Keto-enol tautomerism takes place, followed by release of an acetaldehyde molecule from the palladium. 

Caiboxylate ions are also effective nucleophiles in palladium-catalyzed reactions of alkenes and several classes of lactones including 7-pyrones (equation 11)17 and isocoumarins (equation 12)18 have been made in this manner. These early studies used stoichiometric amounts of palladium salts, since efficient redox systems had not yet been developed. However, with more modem techniques catalysis in these systems should be relatively straightforward. The more recent catalytic cyclization-caibonylation process in equation (13) is indicative of this.19... 

Nucleation is performed by immersion of a sensitized nonconductor into the nucleating solution for 0.5-2 mins. The surface reaction between the stannous ions, Sn2+, adsorbed on the surface of the substrate and the palladium ions, Pd2+, in the nucleator solution is... 

Bidleman et al. (2JD) used a palladium chloride-calcein chelate spray for organothiophosphorus compounds and detected 10 ng per spot. The mechanism is based on the release of the ligand because of the affinity of palladium ions for sulfur atoms. The technique does not necessitate bromine vapours and is therefore an improvement in terms of selectivity. Unfortunately, the reaction is slow and the fluorescence increases with time. 

The results of the thermal analytical studies of Pd-montmorillonite produced from [Pd(NH3)2]2+ and [Pd(en)2]2+ further demonstrate that palladium ions are sorbed on the edge sites. Pd-montmorillonite shows the usual thermal processes of montmorillonites, with two new exothermic reactions at 338°C and 548°C. At around 338°C (maximum) exothermic reaction, a slight weight loss of the sample is also observed in a wide temperature range. It may indicate the partial amorphization of bentonite. At 548°C, the reduction of Pd(II) to Pd(0) may happen. 

Fig. 3. Bi- and mono-nuclear palladium ions observed by ESI(+)-MS and proposed as catalytic intermediates in the enantioselective Manich-type reaction of enol silyl ethers with N-aryl-iminoacetic acid esters 42. ...

Palladium-catalyzed reaction of dienol 80 in acetone in the presence of acetic acid and benzoquinone resulted in an intramolecular 1,4-oxyacetoxylation (Scheme 8-28) [107], The stereochemistry of the reaction can be controlled via a slight variation of the ligand environment. Thus, under chloride-ion-free conditions, a rrawj-oxyacetoxylation occurs. Usually this reaction is highly stereoselective (>98% tram addition), except m = n = 2 in Scheme 8-28, where the tramlcis ratio is 75 25. When the reaction is run in the presence of a catalytic amount of chloride, the stereochemistry is reversed and now a 1,4-cts-oxyacetoxylation takes place. The effect of the chloride is the same as discussed above, i.e., it blocks the coordination of acetate so that cis migration by acetate cannot occur. 

Jutand, A. Mechanism of palladium-catalyzed reactions Role of chloride ions. Applied Organometallic Chemistry 2004, 18, 574-582. 

The alkylation of j p-carbon can, in principle, involve the alkyne (acetylene) either as the nucleophile or the electrophile. In practice by far the most important process involves the alkyne as nucleophile since the acidity of the alkyne proton (pK = 25) allows the ready formation of alkynide ions. These are excellent nucleophiles and they readily undergo acylation and alkylation with appropriate electrophiles. The recent introduction of palladium-catalyzed reactions, usually involving copper(I) salts but also other cations, has greatly increased the use made of arylation and vinylation reactions. In this chapter only the alkylation of the alkynide ion will be discussed acylation, vinylation and arylation reactions are discussed elsewhere. The alkylation of alkynide anions is a reaction of considerable synthetic use and has been extensively reviewed. ... 

The low acidity of 1-alkynes means that strong bases must be used to form the alkynide ions and that water is not a suitable solvent aqueous solutions have a very low concentration of alkynide ions. Some transition metal alkynides can be prepared by precipitation from aqueous solution because their solubilities are very low. Suitable solvents for the preparation of alkynide ions must be less acidic than the alkyne, and preferably allow the alkyne and the alkynide ion to remain in solution. Liquid ammonia, te-trahydrofuran, ether and hydrocarbons have all been used, particularly the first, the alkynide anion being readily formed by metal amides. Alkynides of many types have been prepared from various metals. Besides Groups I and III, copper(I), silver, gold(I), zinc, mercury and, more recently, aluminum alkynides have been synthesized. The alkynides of Groups I and II have been principally used as nucleophiles in alkylation reactions, but there are now many examples of other metal alkynides in this role. Palladium-catalyzed reactions, as remarked above, have become increasingly important for the reactions of alkynides of metals other than Groups I and II, but these have not usually involved alkylation. 

In other redox, homogeneous catalytic reactions, palladium ions catalyze propylene oxidation to acetone 306). The Rashig process 307) is based on benzene oxidation with air in the presence of cupric and ferric chlorides. Toluene and xylene oxidize in solution containing organic salts of Co, Mn, and Mo 308,309). It is interesting to note that in some cases, reoxidation of the active metal ion to its original valence is assumed slow, for example, Cu(I) to Cu(II) 310). It is conceivable that such steps could be assisted and accelerated electrochemically. Conventional processes, then, can provide a starting point for the study and development of new electrochemical redox processes. 

The selectivity of palladium and gold for alkene oxidation to aldehydes 28,29,170) was attributed initially to adsorption strength. However, electrooxidation in the presence of palladium ions indicates possible homogeneous alkene insertion, similar to the Wacker process 304). Homogeneous reaction is also involved in redox oxidations of hydrocarbons. In this case, the nature of the metal ions is expected to control selectivity. Indeed, toluene yields 20% benzaldehyde in electrolytes containing Ce salts, while oxidation proceeds to benzoic acid with Cr redox catalysts 311). In addition, the concentration of redox catalysts appears to affect yields in nonelectrochemical oxidation of ethylene large amounts of palladium chloride promote butene formation at the expense of acetaldehyde 312). Finally, the role of the electrolyte and solvent should not be ignored. For instance, electrooxidation of ethylene on carbon, in aqueous solution of acetic acid yields acetaldehyde 313) in the... 

Alfhough direct nucleophilic addition is limited because of the low nucleophilicity of fhe fluoride ion, a palladium-catalyzed reaction enables the weak nucleophile to participate fhe addition reaction. In the presence of cesium fluoride, palladium-catalyzed carbonylation of an aryl halide gives fhe acyl fluoride in good yield (Scheme 2.5) [8]. 

The optimal acidity corresponds to pH 3.0 0.2. Only Au, Hg, and Pt interfere in determination of palladium. The reaction of TMK with Hg(ll) is slower (about 2 h). Oxidants also interfere the reagent behaves as a reductor. Chloride masks silver ions. EDTA can be used to prevent hydrolysis of some metal ions. 

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