Phosphines, reaction with carbonyl compounds

Rh(CO)2 2(Por) complexes undergo addition reactions with carbonyl compounds and with alkyl halides to give acyl or alkyl Rhul(Por) similar to Rh1(CO)(phosphine)3 (Scheme 33).1.34... 

Treatment of a, -unsaturated carbonyl compounds 18 with nucleophilic selenium species affords -seleno carbonyl compounds 19 in good yields via Michael addition (Scheme 27) [46]. This reaction has been applied to protect a, -unsa-turated lactones [47], in natural product synthesis [48], and in asymmetric Michael additions in the presence of an alkaloid [49]. Michael addition also proceeds with selenolates that are prepared from diphenyl diselenide by cathodic reduction [22], reduction with the Sm-Me3SiCl-H20 system [19], and reduction with tributyl phosphine [25]. 

Reactions of carbonyl carbyne complexes with phosphine ligands or CO lead to the addition of a carbonyl group to the carbyne carbon atom affording ketenyl compounds [scheme (5.143)]. As a result of dissociation of a phosphine or CO molecule, ff-ketenyl... 

One of the first variations of the Wittig reaction was initially reported by Homer and coworkers and rapidly followed by an initial report by Wadsworth and Emmons. These examples made use of phosphine oxide/phosphonate derivatives of the ylides first reported by Wittig and are now collectively known as the Homer-Wadsworth-Emmons reaction (HWE). Ylide formation occurs upon deprotonation of dialkoxy phosphonate 31 and alkene 32 is formed from carbonyl compound 30 with loss of the corresponding phosphate derivative 33. The use of this variation has advantages over the eonventional version a) phosphonate carbanions are known to be more nucleophilic due to decreased stabilization by valence shell expansion of the phosphorous atom, thus are able to react with a wider diversity of carbonyl compounds, b) the phosphorous-based product of the reaction, a water-soluble phosphate, allows for a greater ease of reaction work-up. c) the enhanced reactivity of the phosphonate permits direct derivitization of the reagent, d) the Arbuzov reaction allows for ready preparation of the desired phosphonate. 

Hydroxyall l Hydroperoxyall l Peroxides. There is evidence that hydroxyalkyl hydroperoxyalkyl peroxides (2, X = OH, Y = OOH) exist in equihbrium with their corresponding carbonyl compounds and other a-oxygen-substituted peroxides. For example, reaction with acyl haUdes yields diperoxyesters. Dilute acid hydrolysis yields the corresponding ketone (44). Reduction with phosphines yields di(hydroxyalkyl) peroxides and dehydration results in formation of cycHc diperoxides (4). 

Phosphine oxides may be prepared by the acid-cataly2ed reaction of phosphine with carbonyl compounds such as ketones (94). 

Much better known are the fluonnatedphosphoranes, which have been widely used m the Wittig reaction for the preparation of fluoroolefms Difluoromethylena tion reactions have been effected by using a variety of conditions Treatment of dibromodifluoromethane with two equivalents of tns(dimethylammo)phosphine m carefully dried tnglyme yields a solution of bromodifluoromethylphosphonium broomide, which very effectively converts ketones to difluoromethylene derivatives A more sensitive reagent is prepared by the addihon of two equivalents of the phosphine to the reaction mixture of fluorohalomethane and a carbonyl compound [39, 40] (equation 40) (Table 14)... 

The enantioselective 1,4-addition addition of organometaUic reagents to a,p-unsaturated carbonyl compounds, the so-called Michael reaction, provides a powerful method for the synthesis of optically active compounds by carbon-carbon bond formation [129]. Therefore, symmetrical and unsymmetrical MiniPHOS phosphines were used for in situ preparation of copper-catalysts, and employed in an optimization study on Cu(I)-catalyzed Michael reactions of di-ethylzinc to a, -unsaturated ketones (Scheme 31) [29,30]. In most cases, complete conversion and good enantioselectivity were obtained and no 1,2-addition product was detected, showing complete regioselectivity. Of interest, the enantioselectivity observed using Cu(I) directly in place of Cu(II) allowed enhanced enantioselectivity, implying that the chiral environment of the Cu(I) complex produced by in situ reduction of Cu(II) may be less selective than the one with preformed Cu(I). 

With a-dfsubstituted yUdes the reaction results in the formation of a carbonyl compound and a tertiary phosphine oxide (Scheme 6). 

The results of the reaction of carbonyl compounds, aldehydes and ketones, with NH phosphinous amides can be interpreted as occurring on the PH phos-... 

Wittig reactions are versatile and useful for preparing alkenes, under mild conditions, where the position of the double bond is known unambiguously. The reaction involves the facile formation of a phosphonium salt from an alkyl halide and a phosphine. In the presence of base this loses HX to form an ylide (Scheme 1.15). This highly polar ylide reacts with a carbonyl compound to give an alkene and a stoichiometric amount of a phosphine oxide, usually triphenylphosphine oxide. 

Carbanions derived from phosphine oxides also add to carbonyl compounds. The adducts are stable but undergo elimination to form alkene on heating with a base such as sodium hydride. This reaction is known as the Horner-Wittig reaction.268... 

The reaction of alcohols with CO was catalyzed by Pd compounds, iodides and/or bromides, and amides (or thioamides). Thus, MeOH was carbonylated in the presence of Pd acetate, NiCl2, tV-methylpyrrolidone, Mel, and Lil to give HOAc. AcOH is prepared by the reaction of MeOH with CO in the presence of a catalyst system comprising a Pd compound, an ionic Br or I compound other than HBr or HI, a sulfone or sulfoxide, and, in some cases, a Ni compound and a phosphine oxide or a phosphinic acid.60 Palladium(II) salts catalyze the carbonylation of methyl iodide in methanol to methyl acetate in the presence of an excess of iodide, even without amine or phosphine co-ligands platinum(II) salts are less effective.61 A novel Pd11 complex (13) is a highly efficient catalyst for the carbonylation of organic alcohols and alkenes to carboxylic acids/esters.62... 

Issleib, Oehme, and Zschunke [72MI1 73ZC(13)291 78PS(5)81 79ZC57] obtained secondary phosphines with a y-oxypropyl substituent via the addition of primary phosphines to allyl alcohols and studied their reactions with aldehydes and ketones. Addition of carbonyl compounds proceeds without catalysts at room temperature and is accompanied by... 

A study of the reactions of butadiene, isoprene, or allene coordinated to nickel in a metallacycle, with carbonylic compounds, has been reported by Baker (example 11, Table IV). In the presence of phosphines, these metallacycles adopt a cr-allyl structure on one end and a ir-allyl structure on the other, as mentioned in Section II,A,1. The former is mainly attacked by aldehydes or electrophilic reagents in general, the latter by nucleophiles (C—H acids, see Table I, or amines, see Table IX). 

Ru3(CO)10(Ph2C2)2, and Ru3(CO)9(C2(Ph)2)3 (128). The dinuclear complex Ru2(CO)6(C2Ph2)2, containing a metallocyclopentadiene ring similar to that observed for both iron and osmium, is a further product in the reaction this does imply very similar structures for the trinuclear adducts to those observed for iron and osmium. The carbonyl reacts with tetracyclone to yield the complex Ru3(CO)i0(C2Ph2)2, which may be related to the osmium compounds discussed later. Phosphine substitution of the carbonyls in some of these compounds has been established. 

The reaction of phosphine (produced in situ from magnesium phosphide and hydrogen chloride in dioxan solution) with 1,5-diketones gives106 the phosphorina-none derivatives (104). Carbonyl compounds and heterocumulenes (e.g. CO2, CS2) insert into the germanium-phosphorus bond of germaphospholans to form derivatives of the germaphosphepin system [e.g. (105)].106>107... 

Formate esters behave as typical carbonyl compounds in reactions with a number of ylides, eliminating phosphine oxide and forming vinyl ethers, e.g. (33).35 Stabilized phosphoranes are able to condense with the carbonyl group of cyclic thioanhydrides (34).38 Quinoline derivatives, e.g. (35), are obtained from the condensation of dicar-boalkoxy-ylides with isocyanates.37 Benzoyl isothiocyanates and keto-phosphoranes give quantitative yields of (36), which are unreactive in Wittig reactions but can be readily oxidized by selenous acid.38 The products obtained from reactions (Scheme 9) with the triazolinedione (37) depend upon the stability of the ylide used.39... 

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