Styrenes Wacker process

The Pd-catalyzed conversion of terminal alkenes to methyl ketones is a reaction that has found widespread use in organic chemistry [87,88]. These reactions, as well as the industrial Wacker process, typically employ CuCh as a co-catalyst or a stoichiometric oxidant. Recently Cu-free reaction conditions were identified for the Wacker-type oxidation of styrenes using fBuOOH as the oxidant. An NHC-coordinated Pd complex, in-situ-generated (I Pr)Pd(OTf)2, served as the catalyst (Table 5) [101]. These conditions min-... 

Lead tetraacetate initiates a similar type of oxidation with terminal alkenes, in the presence of acid, to give an aldehyde hy selective oxidation of the terminal carhon. l Ajj example is the conversion of styrene to phenylacetaldehyde in 98% yield. Palladium chloride (PdCl2) reacts with terminal alkenes, in the presence of oxygen and copper salts, to give a methyl ketone (this reaction is called the Wacker process and is discussed in sec. 12.6.A). It is more useful than the LTA oxidation. Oxidation of terminal alkenes with LTA leads to the aldehyde, whereas oxidation with PdCl2 leads to the methyl ketone. The PdCl2 oxidation is illustrated hy conversion of 402 to 403 in 77% yield, in Ikegami s synthesis of coriolin. ... 

Solvent effects on, and products from, reaction of styrene with ethylene in the presence of di-)ti-chloro-dichlorobis(styrene)dipalladium(n), [Pd-(Ph CH—CH2)Cl2]2, indicate a mechanism similar to (i)->(iv) above, with the addition of a preliminary equilibrium between the dimer and solvated monomers. The mechanism of reaction of styrene with vinyl compounds, catalysed by the same chloride-bridged dipalladium complex, has been studied using isotopic tracer (H, D) experiments. Palladium-acetate-catalysed reaction of styrene with benzene, also investigated using deuterium tracer experiments, involves no hydride shift, in contrast to the rather closely related Wacker process. The importance of intermediates with palladium-carbon n-bonds in palladium(ii)-catalysed alkylation and arylation of alkenes has been demonstrated. 

Betzemeier et al. (1998) have used f-BuOOH, in the presence of a Pd(II) catalyst bearing perfluorinated ligands using a biphasic system of benzene and bromo perfluoro octane to convert a variety of olefins, such as styrene, p-substituted styrenes, vinyl naphthalene, 1-decene etc. to the corresponding ketone via a Wacker type process. Xia and Fell (1997) have used the Li salt of triphenylphosphine monosulphonic acid, which can be solubilized with methanol. A hydroformylation reaction is conducted and catalyst recovery is facilitated by removal of methanol when filtration or extraction with water can be practised. The aqueous solution can be evaporated and the solid salt can be dissolved in methanol and recycled. 

To overcome the problems encountered in the homogeneous Wacker oxidation of higher alkenes several attempts have been undertaken to develop a gas-phase version of the process. The first heterogeneous catalysts were prepared by the deposition of palladium chloride and copper chloride on support materials, such as zeolite Y [2,3] or active carbon [4]. However, these catalysts all suffered from rapid deactivation. Other authors applied other redox components such as vanadium pentoxide [5,6] or p-benzoquinone [7]. The best results have been achieved with catalysts based on palladium salts deposited on a monolayer of vanadium oxide spread out over a high surface area support material, such as y-alumina [8]. Van der Heide showed that with catalysts consisting of H2PdCU deposited on a monolayer vanadium oxide supported on y-alumina, ethene as well as 1-butene and styrene... 

The Wacker oxidation was also reahzed with styrene derivatives instead of linear alkene. This study also confirmed the importance of the template during the imprinting process. Styrene derivatives were submitted to the Wacker oxidation conditions in the presence of CD-based MIPs formed in the presence or in the absence of different templates (C16H32 or p-terf-butylstyrene) to evaluate the efficacy of the templating approach. The results are presented in Fig. 2.10. 

PdCl2(CH3CN)2-catalyzed dialkoxylation of internal olefins of styrene derivatives containing an o-phenol unit has been achieved because the o-phenol prevents 8-hydride elimination of the a-alkylpalladium(II) species (eq 7).4 Wacker-type oxidation products are obtained when o-anisole-derived substrates are used instead of o-phenols. Under similar reaction conditions, simple styrene derivatives afford the corresponding acetals or their hydrolysis products. The enantioselective variant of this dialkoxylation process has been subsequently developed. ... 

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