Siloxy

The reaction of benzoyl chloride with (Me3Si)2 affords benzoyltrimethylsi-lane (878)[626,749,750]. Hexamethyldigermane behaves similarly. The siloxy-cyclopropane 879 forms the Pd homoenolate of a ketone and reacts with an acyl halide to form,880. The 1,4-diketone 881 is obtained by reductive elimination of 880 without undergoing elimination of /7-hydrogen[751]. 

Double. silylation of the a-diketone 120 with (Me3Si)2 is catalyzed by PdCl2(Me3P)2 to give the l,2-bis(siloxy)ethylene 121 in a good yield[ll7], Hydro.silylation of phenyl isocyanate (122) catalyzed by PdCN affords the /V-... 

These appHcations are mosdy examples of homogeneous catalysis. Coordination catalysts that are attached to polymers via phosphine, siloxy, or other side chains have also shown promise. The catalytic specificity is often modified by such immobilization. Metal enzymes are, from this point of view, anchored coordination catalysts immobilized by the protein chains. Even multistep syntheses are possible using alternating catalysts along polymer chains. Other polynuclear coordination species, such as the homopoly and heteropoly ions, also have appHcations in reaction catalysis. 

A useful notation and abbreviation of the complex silicone structures takes advantage of the number of oxygen atoms around the silicon atom in a siloxy unit [1]. This notation uses the letters M, D, T and Q to represent siloxy units where the silicon atom is linked with one, two, three or four oxygen atoms, respectively (Scheme 1). Fractions are used in this notation to take into account an equal share of an oxygen atom with adjacent siloxy monomeric units. 

Scheme 1. Notation of siloxy units forming silicone polymers.

When an organofunctional group replaces a methyl group on a siloxy unit, a superscript is used to describe the unit. The most common groups that are encountered can be symbolized as alkyl (R), hydrogen (H), phenyl (Ph), hydroxyl (OH), trifluoropropyl (F), and vinyl (Vi). Thus, vinyl-endblocked-PDMS is represented by (Scheme 3), and a trimethylsiloxy-... 

Linear polymers are the most commonly found, and consist of chains of D units endblocked by a variety of functionalized M units. Branched-chain silicones consist mainly of D units, with a D unit being replaced by a T or a Q unit at each point of branching. Cyclic PDMS oligomers are also common and can play a role in adhesion. They are usually found as mixtures of structures going from three siloxy units, to four, five, and higher siloxy units. A whole range of analytical techniques can determine the detailed molecular structures of these materials [20,21],... 

Upon application of the silicone by extrusion, moisture in the atmosphere comes into contact with the silicone surface. The hydrolysis of an acetoxy siloxy group of the diacetoxymethylsiloxy-endblocked-PDMS reactive polymer (II) proceeds and leads to a silanol-endblocked polymer as shown in Scheme 7, where OAc represents the acetoxy (CH3COO-) group. 

The resulting silanol group of a polymer chain condenses with acetoxy siloxy group of another polymer chain to form a siloxane (Si-O-Si) linkage (Scheme 8). Further similar reactions finally result in a crosslinked elastomer. Acetic acid is... 

Reactions of ar>l or alkyl bis(siloxy)isopropyl ethers with tetrabutyl-ammoninm fluoride-mesyl fluoride reagent lead to replacement of one siloxy group by fluorine and dehydrosiloxylation, providing an efficient access to fluoroisopropenyl ethers, which are useful as specific building blocks in drug design The reactions proceed via the intermediate allyl methanesulfonates [30, 31] (equation 23)... 

In most of the successful Diels-Alder reactions reported, dienes containing no heteroatom have been employed, and enantioselective Diels-Alder reactions of multiply heteroatom-substituted dienes, e.g. Danishefsky s diene, are rare, despite their tremendous potential usefulness in complex molecular synthesis. Rawal and coworkers have reported that the Cr(III)-salen complex 15 is a suitable catalyst for the reaction of a-substituted a,/ -unsubstituted aldehydes with l-amino-3-siloxy dienes [21] (Scheme 1.28, Table 1.12). The counter-ion of the catalyst is important and good results are obtained in the reaction using the catalyst paired with the SbFg anion. 

Extraordinarily high Cram selectivity was reported for the reaction of 2-propenyltriisopro-poxytitanium with a-siloxy ketones88. 

Deprotonation of the vinylic proton is a serious side-reaction in the conjugate addition of organometallic reagents to y-siloxy-a, /J-unsaturated sulfones (89)63b. The use of the... 

Reaction with Electron-Rich Siloxy-Substituted 1,3-Dienes. 79... 

Coupling of alkenylcarbene complexes and siloxy-substituted 1,3-dienes affords vinylcyclopentene derivatives through a formal [3C+2S] cycloaddition process. This unusual reaction is explained by an initial [4C+2S] cycloaddition of the electron-poor chromadiene system as the 471 component and the terminal double bond of the siloxydiene as the dienophile. The chromacyclohexene intermediate evolves by a reductive elimination of the metal fragment to generate the [3C+2S] cyclopentene derivatives [73] (Scheme 26). 

A proposed mechanism for silyl ether displacement is shown in Scheme 6.14. In the first step, the fluoride anion converts the trimethyl siloxy group into a phe-nolate salt. In the following step, the phenolate anion attacks the activated fluoro monomer to generate an ether bond. The amount of catalyst required is about 0.1-0.3 mol%. Catalyst type and concentration are crucial for this reaction. 

Many types of phosphorus-phosphorus bonds are known, but it is rare to find such bonds in hexacoordinated phosphorus compounds (with the exception of 57). Cavell reported in 1998 the reaction of PCI5 with phenylbis(o-(trimethyl-siloxy)phenyl)phosphane, yielding the corresponding bischelate 61 in decent yield (52%) [99]. The octahedral nature of the central phosphorus atom was unambiguously determined by X-ray structural analysis. Two short axial bonds (2.202 A) lie perpendicular to the pseudo-octahedral equatorial plane. 

Scheme 9). Although cyanohydrin acetonide 64 could conceivably have been used, the silyl ether 75 was chosen. This compound is readily available from (l)-malic acid, and can undergo electrophilic activation under far more mild conditions than compound 64. Alkylation of the 1,3-diol synthon 75 with bromide 76 created the C11-C26 framework of roflamycoin, in 85% yield. A two-step conversion of the terminal siloxy group to the primary iodide (78) proceeded in 80% overall yield. 

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