Stoichiometric Carbonylation Using Carbonyl Complexes

Stoichiometric Carbonylation using Carbonyl Complexes 4.5.1 Iron and Cobalt Carbonyl Anions... 

SEGPHOS [271, 272]. Using this complex as a precatalyst, transfer hydrogenation of 1,1-dimethylallene in the presence of diverse aldehydes mediated by isopropanol delivers products of ferf-prenylation in good to excellent yield and with excellent levels of enantioselectivity. In the absence of isopropanol, enantio-selective carbonyl reverse prenylation is achieved directly from the alcohol oxidation level to furnish an equivalent set of adducts. Notably, enantioselective ferf-prenylation is achieved under mild conditions (30-50°C) in the absence of stoichiometric metallic reagents. Indeed, for reactions conducted from the alcohol oxidation level, stoichiometric byproducts are completely absent (Scheme 13). 

Since the early 2000s, different sources of CO have been explored and applied to carbonylation reactions for laboratory organic synthesis. For example, the use a stoichiometric amount of metal-carbonyl complexes, thermolysis of formic acid at high temperature, and the use of aldehydes via decarbonylation have been investigated. For the use of metal-carbonyl complexes and formaldehyde as carbonyl source, it has been shown that microwave irradiation greatly accelerates the process. ... 

The stoichiometric carbonylation observed using [HRu(CO)3] and the proposed catalytic schemes all involve tricarbonyl species as the active catalyst the relatively high activity of Ru3(CO)i2 is consistent with this. The relative activity of the complexes for piperidine carbonylation is [HRu(CO)3L Ru3(CO)12 > [Ru(CO)2(OCOMe)]n. The major cause of the decrease in carbonylation rates is the accumulation of formyl product although the decrease in amine concentration is also a contributing factor. This catalyst poisoning is likely attributable to com-plexation to the ruthenium, presumably via the carbonyl grouping as commonly found for formamide ligands (26). The product could compete with either amine or CO for a metal coordination site. 

The reaction of iron-carbonyl complexes with alkynes led to cyclobutenediones, which is formally a [2 + 1 + 1]-cycloaddition process for the formation of a cyclobutene derivative (Scheme 9.22) [49]. Nevertheless, in this reaction the liberation of the ligand is initiated by addition of stoichiometric amounts of copper] 11) salts and the use of various alkynes leads to interesting products such as 30 in good yields. 

Synthetic Reactions Using Carbene Complexes of Metal Carbonyls as Stoichiometric Reagents... 

Thus, in the fine chemicals industry, reduction of ketones and aldehydes relies mainly on the use of complex metal hydrides that require time-consuming workup of reaction mixtures and produce significant amounts of inorganic and organic wastes. Similarly, the oxidation of alcohols into carbonyls is traditionally performed with stoichiometric inorganic oxidants, notably Cr(VI) reagents or a catalyst in combination with a stoichiometric oxidant [1]. 

Among the carbonylative cycloaddition reactions, the Pauson-Khand (P-K) reaction, in which an alkyne, an alkene, and carbon monoxide are condensed in a formal [2+2+1] cycloaddition to form cyclopentenones, has attracted considerable attention [3]. Significant progress in this reaction has been made in this decade. In the past, a stoichiometric amount of Co2(CO)8 was used as the source of CO. Various additive promoters, such as amines, amine N-oxides, phosphanes, ethers, and sulfides, have been developed thus far for a stoichiometric P-K reaction to proceed under milder reaction conditions. Other transition-metal carbonyl complexes, such as Fe(CO)4(acetone), W(CO)5(tetrahydrofuran), W(CO)5F, Cp2Mo2(CO)4, where Cp is cyclopentadienyl, and Mo(CO)6, are also used as the source of CO in place of Co2(CO)8. There has been significant interest in developing catalytic variants of the P-K reaction. Rautenstrauch et al. [4] reported the first catalytic P-K reaction in which alkenes are limited to reactive alkenes, such as ethylene and norbornene. Since 1994 when Jeong et al. [5] reported the first catalytic intramolecular P-K reaction, most attention has been focused on the modification of the cobalt catalytic system [3]. Recently, other transition-metal complexes, such as Ti [6], Rh [7], and Ir complexes [8], have been found to be active for intramolecular P-K reactions. 

Although a whole series of carbonyl complexes of other transition metals (Fe, Mo, W, Ni) could only be used in stoichiometric Pauson-Khand reactions [11], two Japanese laboratories have since independently reported efficient ruthenium-catalyzed (intramolecular) reactions. The desired cy-clopentenones are formed in good to excellent yields in dimethylacetamide [12] or dioxane [13] in the presence of 2 mol% of [Ru3(CO),2] at 140-160 °C and 10-13 atm CO pressure. 

Oxidative addition of organic halides to low-valent metal complexes generates reactive metal alkyls that can then be used in insertion, coupling, carbonylation-decar-bonylation and cyclization reactions for organic synthesis. These transformations can be made catalytic after development of the stoichiometric chemistry using the more stable metal alkyls. This section surveys the reactions of alkyl, aryl and acyl halides with transition metal complexes of the groups IIIA (lanthanides and actinides), IVA-VIII and IB. 

Cobalt complexes have been used to catalyze the carbonylation of chloroarenes to the corresponding carboxylic acids and their esters (Sect. 3.3). Some complexes of cobalt in the oxidation state -1 activate the Ar-Cl bond via an SRN1-type mechanism [2] involving single electron transfer from the metal to chloro-arene, followed by elimination of Cl . The simplest Co(-I) carbonyl species, [Co(CO)4] , is not electron-rich enough to react with haloarenes. However, its reactivity has been shown to enhance tremendously in the presence of Caubere s complex bases, mixtures of NaH and NaOAlk [23,66,67]. For instance, the stoichiometric carbonylation of chlorobenzene has been performed with the... 

Another important development in the area of catalytic Pauson-Khand type cy-clizations has been the discovery of other transition metal carbonyl complexes which are capable of effecting the catalytic synthesis of cyclopentenones. Two recent reports from Murai and Mitsudo detailed a Ru3(CO)i2-catalyzed enyne cyclocarbonylation, Eqs. (10) and (11) [34,35]. While this protocol allowed for the cyclization of a variety of l,6-enynes,the cyclizations of terminal alkynes as well as 1,7-enynes were problematic. The feasibility of using Cp2Ti(CO)2 as a catalyst for the intramolecular Pauson-Khand type cyclization of a variety of 1,6-and 1,7-enynes (vide infra) has also been demonstrated [36]. Based on the wide array of transition metals that are capable of effecting stoichiometric Pauson-Khand type cyclizations (vide supra), the development of more catalytic systems is to be expected this should greatly facilitate the search for catalytic asymmetric variants. 

A wine-red hydridoiron carbonyl complex generated in situ from Fe(CO)5 and a small amount of base in moist solvents can be used in a stoichiometric manner for the hydrogenation and deuteration of a,jS-unsaturated ketones, aldehydes, esters, and lactones. The mixture stands at RT for —12 h, and yields are often greater than 90% ° ... 

The history of direct DPC process development at GE can be considered as a case study. In the mid-1970s. Chalk discovered that /rara-substituted phenols can be oxidatively carbonylated using stoichiometric amounts of a Ru, Rh, Os, Ir, or Pd salt, from which the palladium salts were the most active (Eq. (12.3)) [5]. Yields of carbonylation products were high, but the reaction yielded 1 mol of Pd° for every mole of product, so it was stoichiometric [6]. In the late 1970s, Hallgren and Matthews assumed that DPC was formed by reductive elimination from the acyl Pd(ll) carbonyl complex [7]. 

Direct carbonylation of primary amines to give N,N -symmetrical ureas can be achieved in good yield (56-67%) using a nitrido tungsten(IV) carbonyl complex. The reaction is carried out at room temperature under nitrogen, and is followed by oxidation with air at ambient pressure. Unfortunately, the process requires a stoichiometric amount of the carbonyl complex, and ureas are only obtained with primary amines since secondary amines afford formamides [763]. 

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